{"refrec":{"BRefID":123796,"RR":"Nature Geoscience. Nature Publishing Group: London.  ISSN 1752-0894; e-ISSN 1752-0908","BEntID":118012,"PublicFlag":1,"CheckedFlag":0,"wosflag":1,"vabbflag":1,"RefStringPartII":". Nature Publishing Group: London.  ISSN 1752-0894; e-ISSN 1752-0908","DocTypID":16,"DocType":"Journal","MarineFlag":0,"FreshFlag":0,"BrackishFlag":0,"TerrestrialFlag":0,"Authorstring":null,"OrigTitleTranslFlag":0,"Authorstringtrunc":null,"Englishabstract":null,"AbstractOtherLang":null,"BibLvlCode":"S","StandardTitle":"Nature Geoscience","OrigTitleLangCode":"en","OrigTitleLangCodeExtended":"eng","OrigTitleLangID":15,"DateLastModified":{"date":"2024-12-10 01:33:17.368041","timezone_type":1,"timezone":"+01:00"},"UserAccessRight":null,"UserAccID":null,"AuthorKeywords":null,"OtherDescriptors":null,"Notes":null,"AnaPub":null,"MonPub":null,"DateUpdate":"2015-08-11","DateCreate":"2008-07-14","SecASFANote":null,"ConfID":null,"PeerRev":1,"VlizCoreFlag":1,"WoScode":null,"VABBcode":null,"OpenAcc":0},"refs":null,"anarec":null,"monrec":null,"serrec":{"SerID":123796,"ISSN":"1752-0894","Abbreviation":"Nature Geoscience","PublID":2828,"City":"London","InpCentreCode":null,"ASFACode":null,"AntilopeFlag":0,"PerioID":null,"CurrentFlag":1,"PeerRevFlag":1,"DigISSN":"1752-0908","InputCentre":null,"Periodicity":null,"FromYear":2008,"ToYear":null,"WoSFlag":1,"ISSNL":"1752-0894","EmbargoYears":null,"VABBFlag":1},"relations":null,"relationsRev":null,"addrec":null,"othpubs":null,"ownerships":null,"authors":null,"mapdetails":null,"datasets":null,"monographs":null,"monparts":null,"serparts":[{"BRefID":337161,"RR":"<b>Peiffer, S.; Kappler, A.; Haderlein, S.B.; Schmidt, C.; Byrne, J.M.; Kleindienst, S.; Vogt, C.; Richnow, H.H.; Obst, M.; Angenent, L.T.; Bryce, C.; McCammon, C.; Planer-Friedrich, B.</b> (2021). A biogeochemical–hydrological framework for the role of redox-active compounds in aquatic systems. <i>Nature Geoscience 14(5)</i>: 264-272. <a href=\"https://hdl.handle.net/10.1038/s41561-021-00742-z\" target=\"_blank\">https://hdl.handle.net/10.1038/s41561-021-00742-z</a>","StandardTitle":"A biogeochemical–hydrological framework for the role of redox-active compounds in aquatic systems","AuthorsString":"Peiffer, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396172,"RR":"<b>Smit, M.A.; Kooijman, E.</b> (2024). A common precursor for global hotspot lavas. <i>Nature Geoscience 17(10)</i>: 1053-1058. <a href=\"https://dx.doi.org/10.1038/s41561-024-01538-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01538-7</a>","StandardTitle":"A common precursor for global hotspot lavas","AuthorsString":"Smit, M.A.; Kooijman, E.","BibLvlCode":"AS"},{"BRefID":308738,"RR":"<b>Farinotti, D.; Huss, M.; Fürst, J.J.; Landmann, J.; Machguth, H.; Maussion, F.; Pandit, A.</b> (2019). A consensus estimate for the ice thickness distribution of all glaciers on Earth. <i>Nature Geoscience 12(3)</i>: 168-173. <a href=\"https://dx.doi.org/10.1038/s41561-019-0300-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0300-3</a>","StandardTitle":"A consensus estimate for the ice thickness distribution of all glaciers on Earth","AuthorsString":"Farinotti, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":243202,"RR":"<b>Parnell-Turner, R.; White, N.; Henstock, T.; Murton, B.J.; Maclennan, J.; Jones, S.M.</b> (2014). A continuous 55-million-year record of transient mantle plume activity beneath Iceland. <i>Nature Geoscience 7(12)</i>: 914–919. <a href=\"http://dx.doi.org/10.1038/ngeo2281\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2281</a>","StandardTitle":"A continuous 55-million-year record of transient mantle plume activity beneath Iceland","AuthorsString":"Parnell-Turner, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":253107,"RR":"<b>Pauly, D.; Froese, R.</b> (2010). A count in the dark. <i>Nature Geoscience 3(10)</i>: 662-663. <a href=\"https://dx.doi.org/10.1038/ngeo973\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo973</a>","StandardTitle":"A count in the dark","AuthorsString":"Pauly, D.; Froese, R.","BibLvlCode":"AS"},{"BRefID":363728,"RR":"<b>Kilbourne, K.H.</b> (2023). A current take on past overturning. <i>Nature Geoscience 16(4)</i>: 286-287. <a href=\"https://dx.doi.org/10.1038/s41561-023-01158-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01158-7</a>","StandardTitle":"A current take on past overturning","AuthorsString":"Kilbourne, K.H.","BibLvlCode":"AS"},{"BRefID":211509,"RR":"<b>Deschamps, F.; Kaminski, E.; Tackley, P.J.</b> (2011). A deep mantle origin for the primitive signature of ocean island basalt. <i>Nature Geoscience 4(12)</i>: 879-882. <a href=\"http://dx.doi.org/10.1038/ngeo1295\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1295</a>","StandardTitle":"A deep mantle origin for the primitive signature of ocean island basalt","AuthorsString":"Deschamps, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":345755,"RR":"<b>Pilarczyk, J.E.; Sawai, Y.; Namegaya, Y.; Tamura, T.; Tanigawa, K.; Matsumoto, D.; Shinozaki, T.; Fujiwara, O.; Shishikura, M.; Shimada, Y.; Dura, T.; Horton, B.P.; Parnell, A.C.; Vane, C.H.</b> (2021). A further source of Tokyo earthquakes and Pacific Ocean tsunamis. <i>Nature Geoscience 14(10)</i>: 796-800. <a href=\"https://dx.doi.org/10.1038/s41561-021-00812-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00812-2</a>","StandardTitle":"A further source of Tokyo earthquakes and Pacific Ocean tsunamis","AuthorsString":"Pilarczyk, J.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":436562,"RR":"<b>Coggon, R.M.; Carter, E.J.; Grant, L.J.C.; Evans, A.D.; Lowery, C.M.; Teagle, D.A.H.; Kempton, P.D.; Cooper, M.J.; Routledge, C.M.; Albers, E.; Estep, J.; Christeson, G.L.; Harris, M.; Belgrano, T.M.; Sylvan, J.B.; Reece, J.S.; Estes, E.R.; Williams, T.</b> (2025). A geological carbon cycle sink hosted by ocean crust talus breccias. <i>Nature Geoscience 18(12)</i>: 1279-1286. <a href=\"https://dx.doi.org/10.1038/s41561-025-01839-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01839-5</a>","StandardTitle":"A geological carbon cycle sink hosted by ocean crust talus breccias","AuthorsString":"Coggon, R.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":247383,"RR":"<b>Guilbaud, R.; Poulton, S.W.; Butterfield, N.J.; Zhu, M.; Shields-Zhou, G.</b> (2015). A global transition to ferruginous conditions in the early Neoproterozoic oceans. <i>Nature Geoscience 8(6)</i>: 466–470. <a href=\"http://dx.doi.org/10.1038/ngeo2434\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2434</a>","StandardTitle":"A global transition to ferruginous conditions in the early Neoproterozoic oceans","AuthorsString":"Guilbaud, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":302861,"RR":"<b>Polyak, V.J.; Onac, B.P.; Fornós, J.J.; Hay, C.C.; Asmerom, Y.; Dorale, J.A.; Ginés, J.; Tuccimei, P.; Ginés, A.</b> (2018). A highly resolved record of relative sea level in the western Mediterranean Sea during the last interglacial period. <i>Nature Geoscience 11(11)</i>: 860-864. <a href=\"https://dx.doi.org/10.1038/s41561-018-0222-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0222-5</a>","StandardTitle":"A highly resolved record of relative sea level in the western Mediterranean Sea during the last interglacial period","AuthorsString":"Polyak, V.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":258273,"RR":"<b>Reddy, C.M.</b> (2016). A hump in ocean–air exchange. <i>Nature Geoscience 9(6)</i>: 415-416. <a href=\"http://dx.doi.org/10.1038/ngeo2716\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2716</a>","StandardTitle":"A hump in ocean–air exchange","AuthorsString":"Reddy, C.M.","BibLvlCode":"AS"},{"BRefID":371757,"RR":"<b>Kim, T.; O’Rourke, J.G.; Lee, J.; Chariton, S.; Prakapenka, V.; Husband, R.J.; Giordano, N.; Liermann, H.-P.; Shim, S.-H.; Lee, Y.</b> (2023). A hydrogen-enriched layer in the topmost outer core sourced from deeply subducted water. <i>Nature Geoscience 16(12)</i>: 1208-1214. <a href=\"https://dx.doi.org/10.1038/s41561-023-01324-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01324-x</a>","StandardTitle":"A hydrogen-enriched layer in the topmost outer core sourced from deeply subducted water","AuthorsString":"Kim, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":283197,"RR":"<b>Halevy, I.; Alesker, M.; Schuster, E.M.; Popovitz-Biro, R.; Feldman, Y.</b> (2017). A key role for green rust in the Precambrian oceans and the genesis of iron formations. <i>Nature Geoscience 10(2)</i>: 135-139. <a href=\"http://dx.doi.org/10.1038/ngeo2878\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2878</a>","StandardTitle":"A key role for green rust in the Precambrian oceans and the genesis of iron formations","AuthorsString":"Halevy, I. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":249207,"RR":"<b>Leri, A.C.; Mayer, L.M.; Thornton, K.R.; Northrup, P.A.; Dunigan, M.R.; Ness, K.J.; Gellis, A.B.</b> (2015). A marine sink for chlorine in natural organic matter. <i>Nature Geoscience 8(8)</i>: 620-624. <a href=\"http://dx.doi.org/10.1038/ngeo2481\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2481</a>","StandardTitle":"A marine sink for chlorine in natural organic matter","AuthorsString":"Leri, A.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":289760,"RR":"<b>Dickson, A.J.</b> (2017). A molybdenum-isotope perspective on Phanerozoic deoxygenation events. <i>Nature Geoscience 10(10)</i>: 721-726. <a href=\"https://dx.doi.org/10.1038/ngeo3028\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3028</a>","StandardTitle":"A molybdenum-isotope perspective on Phanerozoic deoxygenation events","AuthorsString":"Dickson, A.J.","BibLvlCode":"AS"},{"BRefID":242739,"RR":"<b>Marjanovic, M.; Carbotte, S.M.; Carton, H.; Nedimovic, M.R.; Mutter, J.C.; Canales, J.P.</b> (2014). A multi-sill magma plumbing system beneath the axis of the East Pacific Rise. <i>Nature Geoscience 7(11)</i>: 825–829. <a href=\"http://dx.doi.org/10.1038/ngeo2272\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2272</a>","StandardTitle":"A multi-sill magma plumbing system beneath the axis of the East Pacific Rise","AuthorsString":"Marjanovic, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":438826,"RR":"<b>Sergienko, O.; Haseloff, M.; Robel, A.; Wingham, D.</b> (2026). A new paradigm for understanding Earth’s marine ice sheets. <i>Nature Geoscience 19(4)</i>: 374-383. <a href=\"https://dx.doi.org/10.1038/s41561-026-01941-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01941-2</a>","StandardTitle":"A new paradigm for understanding Earth’s marine ice sheets","AuthorsString":"Sergienko, O. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":329222,"RR":"<b>Schobben, M.; Foster, W.J.; Sleveland, A.R.V.; Zuchuat, V.; Svensen, H.H.; Planke, S.; Bond, D.P.G.; Marcelis, F.; Newton, R.J.; Wignall, P.B.; Poulton, S.W.</b> (2020). A nutrient control on marine anoxia during the end-Permian mass extinction. <i>Nature Geoscience 13(9)</i>: 640-646. <a href=\"https://dx.doi.org/10.1038/s41561-020-0622-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0622-1</a>","StandardTitle":"A nutrient control on marine anoxia during the end-Permian mass extinction","AuthorsString":"Schobben, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":294037,"RR":"<b>Spencer, C.J.; Murphy, J.B.; Kirkland, C.L.; Liu, Y.; Mitchell, R.N.</b> (2018). A Palaeoproterozoic tectono-magmatic lull as a potential trigger for the supercontinent cycle. <i>Nature Geoscience 11(2)</i>: 97-101. <a href=\"https://dx.doi.org/10.1038/s41561-017-0051-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0051-y</a>","StandardTitle":"A Palaeoproterozoic tectono-magmatic lull as a potential trigger for the supercontinent cycle","AuthorsString":"Spencer, C.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":336521,"RR":"<b>Lobo, A.H.; Thompson, A.F.; Vance, S.D.; Tharimena, S.</b> (2021). A pole-to-equator ocean overturning circulation on Enceladus. <i>Nature Geoscience 14(4)</i>: 185-189. <a href=\"https://dx.doi.org/10.1038/s41561-021-00706-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00706-3</a>","StandardTitle":"A pole-to-equator ocean overturning circulation on Enceladus","AuthorsString":"Lobo, A.H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":348084,"RR":"<b>Waszek, L.; Tauzin, B.; Schmerr, N.C.; Ballmer, M.D.; Afonso, J.C.</b> (2021). A poorly mixed mantle transition zone and its thermal state inferred from seismic waves. <i>Nature Geoscience 14(12)</i>: 949-955. <a href=\"https://dx.doi.org/10.1038/s41561-021-00850-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00850-w</a>","StandardTitle":"A poorly mixed mantle transition zone and its thermal state inferred from seismic waves","AuthorsString":"Waszek, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":341642,"RR":"<b>Van Hinsbergen, D.J.J.; Steinberger, B.; Guilmette, C.; Maffione, M.; Gürer, D.; Peters, K.; Plunder, A.; McPhee, P.J.; Gaina, C.; Advokaat, E.L.; Vissers, R.L.M.; Spakman, W.</b> (2021). A record of plume-induced plate rotation triggering subduction initiation. <i>Nature Geoscience 14(8)</i>: 626-630. <a href=\"https://dx.doi.org/10.1038/s41561-021-00780-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00780-7</a>","StandardTitle":"A record of plume-induced plate rotation triggering subduction initiation","AuthorsString":"Van Hinsbergen, D.J.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":249482,"RR":"<b>Arculus, R.J.; Ishizuka, O.; Bogus, K.A.; Gurnis, M.; Hickey-Vargas, R.; Aljahdali, M.H.; Bandini-Maeder, A.N.; Barth, A.P.; Brandi, P.A.; Drab, L.; do Monte Guerra, R.; Hamda, M.; Jiang, F.; Kanayama, K.; Kender, S.; Kusano, Y.; Li, H.; Loudin, L.C.; Maffione, M.; Marsaglia, K.M.; McCathy, A.; Meffre, S.; Morris, A.; Neuhaus, M.; Savov, I.P.; Sena, C.; Tepley III, F.J.; van der Land, C.; Yogodzinski, G.M.; Zhang, Z.</b> (2015). A record of spontaneous subduction initiation in the Izu–Bonin–Mariana arc. <i>Nature Geoscience 8(9)</i>: 728–733. <a href=\"http://dx.doi.org/10.1038/ngeo2515\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2515</a>","StandardTitle":"A record of spontaneous subduction initiation in the Izu–Bonin–Mariana arc","AuthorsString":"Arculus, R.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":259365,"RR":"<b>Robson, J.; Ortega, P.; Sutton, R.</b> (2016). A reversal of climatic trends in the North Atlantic since 2005. <i>Nature Geoscience 9(7)</i>: 513-517. <a href=\"http://dx.doi.org/10.1038/ngeo2727\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2727</a>","StandardTitle":"A reversal of climatic trends in the North Atlantic since 2005","AuthorsString":"Robson, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":438185,"RR":"<b>He, R.; Pohl, A.; Zhang, X.; Chang, C.; Prow-Fleischer, A.; Payne, J.L.; Xiao, S.; Ridgwell, A.; Lu, Z.</b> (2026). A reversed latitudinal ocean oxygen gradient in the Proterozoic Eon. <i>Nature Geoscience 19(3)</i>: 325-330. <a href=\"https://dx.doi.org/10.1038/s41561-025-01896-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01896-w</a>","StandardTitle":"A reversed latitudinal ocean oxygen gradient in the Proterozoic Eon","AuthorsString":"He, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291304,"RR":"<b>Hwang, H.; Seoung, D.; Lee, Y.; Liu, Z.; Liermann, H.-P.; Cynn, H.; Vogt, T.; Kao, C-C.; Mao, H.-K.</b> (2017). A role for subducted super-hydrated kaolinite in Earth’s deep water cycle. <i>Nature Geoscience 10(12)</i>: 947-953. <a href=\"https://dx.doi.org/10.1038/s41561-017-0008-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0008-1</a>","StandardTitle":"A role for subducted super-hydrated kaolinite in Earth’s deep water cycle","AuthorsString":"Hwang, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":348081,"RR":"<b>Knorr, G.; Barker, S.; Zhang, X.; Lohmann, G.; Gong, X.; Gierz, P.; Stepanek, C.; Stap, L.B.</b> (2021). A salty deep ocean as a prerequisite for glacial termination. <i>Nature Geoscience 14(12)</i>: 930-936. <a href=\"https://dx.doi.org/10.1038/s41561-021-00857-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00857-3</a>","StandardTitle":"A salty deep ocean as a prerequisite for glacial termination","AuthorsString":"Knorr, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":394034,"RR":"<b>Walshaw, C.V.; Gray, A.; Fretwell, P.T.; Convey, P.; Davey, M.P.; Johnson, J.S.; Colesie, C.</b> (2024). A satellite-derived baseline of photosynthetic life across Antarctica. <i>Nature Geoscience 17(8)</i>: 755-762. <a href=\"https://dx.doi.org/10.1038/s41561-024-01492-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01492-4</a>","StandardTitle":"A satellite-derived baseline of photosynthetic life across Antarctica","AuthorsString":"Walshaw, C.V. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366129,"RR":"<b>Vermassen, F.; O'Regan, M.; de Boer, A.; Schenk, F.; Razmjooei, M.; West, G.; Cronin, T.M.; Jakobsson, M.; Coxall, H.K.</b> (2023). A seasonally ice-free Arctic Ocean during the Last Interglacial. <i>Nature Geoscience 16(8)</i>: 723-729. <a href=\"https://dx.doi.org/10.1038/s41561-023-01227-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01227-x</a>","StandardTitle":"A seasonally ice-free Arctic Ocean during the Last Interglacial","AuthorsString":"Vermassen, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":408004,"RR":"<b>Liang, X.; Stüeken, E.E.; Alessi, D.S.; Konhauser, K.O.; Li, L.</b> (2025). A seawater oxygen oscillation recorded by iron formations prior to the Great Oxidation Event. <i>Nature Geoscience 18(5)</i>: 417-422. <a href=\"https://dx.doi.org/10.1038/s41561-025-01683-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01683-7</a>","StandardTitle":"A seawater oxygen oscillation recorded by iron formations prior to the Great Oxidation Event","AuthorsString":"Liang, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":327892,"RR":"<b>Ohmoto, H.</b> (2020). A seawater-sulfate origin for early Earth’s volcanic sulfur. <i>Nature Geoscience 13(8)</i>: 576-583. <a href=\"https://dx.doi.org/10.1038/s41561-020-0601-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0601-6</a>","StandardTitle":"A seawater-sulfate origin for early Earth’s volcanic sulfur","AuthorsString":"Ohmoto, H.","BibLvlCode":"AS"},{"BRefID":316662,"RR":"<b>Poitrasson, F.</b> (2019). A silicon memory of subduction. <i>Nature Geoscience 12(9)</i>: 682-683. <a href=\"https://dx.doi.org/10.1038/s41561-019-0418-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0418-3</a>","StandardTitle":"A silicon memory of subduction","AuthorsString":"Poitrasson, F.","BibLvlCode":"AS"},{"BRefID":320560,"RR":"<b>Ielpi, A.; Lapôtre, M.G.A.</b> (2020). A tenfold slowdown in river meander migration driven by plant life. <i>Nature Geoscience 13(1)</i>: 82-86. <a href=\"https://dx.doi.org/10.1038/s41561-019-0491-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0491-7</a>","StandardTitle":"A tenfold slowdown in river meander migration driven by plant life","AuthorsString":"Ielpi, A.; Lapôtre, M.G.A.","BibLvlCode":"AS"},{"BRefID":341637,"RR":"<b>Tsekhmistrenko, M.; Sigloch, K.; Hosseini, K.; Barruol, G.</b> (2021). A tree of Indo-African mantle plumes imaged by seismic tomography. <i>Nature Geoscience 14(8)</i>: 612-619. <a href=\"https://dx.doi.org/10.1038/s41561-021-00762-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00762-9</a>","StandardTitle":"A tree of Indo-African mantle plumes imaged by seismic tomography","AuthorsString":"Tsekhmistrenko, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":248281,"RR":"<b>Grefe, I.</b> (2015). A tropical hotspot. <i>Nature Geoscience 8(7)</i>: 504–505. <a href=\"http://dx.doi.org/10.1038/ngeo2473\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2473</a>","StandardTitle":"A tropical hotspot","AuthorsString":"Grefe, I.","BibLvlCode":"AS"},{"BRefID":310823,"RR":"<b>Duran Vinent, O.; Andreotti, B.; Claudin, P.; Winter, C.</b> (2019). A unified model of ripples and dunes in water and planetary environments. <i>Nature Geoscience 12(5)</i>: 345-350. <a href=\"https://dx.doi.org/10.1038/s41561-019-0336-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0336-4</a>","StandardTitle":"A unified model of ripples and dunes in water and planetary environments","AuthorsString":"Duran Vinent, O. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":408006,"RR":"<b>Horgan, Huw J.; Stewart, Craig; Stevens, Craig; Dunbar, Gavin; Balfoort, Linda; Schmidt, Britney E.; Washam, Peter; Werder, Mauro A.; Mandeno, Darcy; Marschalek, James; Hulbe, Christina; Holschuh, Nicholas; Levy, Richard; Hurwitz, Benjamin; Jendersie, Stefan; Johnson, Katelyn; Lawrence, Justin; Morgenstern, Regine; Mullen, Andrew D.; Quartini, Enrica; Sauthoff, Wilson; Siegfried, Matthew; Still, Holly; Thorpe-Loversuch, Sam; van de Flierdt, Tina; Venturelli, Ryan; Whiteford, Arran</b> (2025). A west Antarctic grounding-zone environment shaped by episodic water flow. <i>Nature Geoscience 18(5)</i>: 389-395. <a href=\"https://dx.doi.org/10.1038/s41561-025-01687-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01687-3</a>","StandardTitle":"A west Antarctic grounding-zone environment shaped by episodic water flow","AuthorsString":"Horgan, Huw J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359754,"RR":"<b>Nishizawa, M.</b> (2022). Abiotic path of Archean nitrogen. <i>Nature Geoscience 15(12)</i>: 962-963. <a href=\"https://dx.doi.org/10.1038/s41561-022-01072-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01072-4</a>","StandardTitle":"Abiotic path of Archean nitrogen","AuthorsString":"Nishizawa, M.","BibLvlCode":"AS"},{"BRefID":333776,"RR":"<b>Bauska, T.K.; Marcott, S.A.; Brook, E.J.</b> (2021). Abrupt changes in the global carbon cycle during the last glacial period. <i>Nature Geoscience 14(2)</i>: 91-96. <a href=\"https://dx.doi.org/10.1038/s41561-020-00680-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00680-2</a>","StandardTitle":"Abrupt changes in the global carbon cycle during the last glacial period","AuthorsString":"Bauska, T.K.; Marcott, S.A.; Brook, E.J.","BibLvlCode":"AS"},{"BRefID":345736,"RR":"<b>Osman, M.B.; Smith, B.E.; Trusel, L.D.; Das, S.B.; McConnell, J.R.; Chellman, N.; Arienzo, M.; Sodemann, H.</b> (2021). Abrupt Common Era hydroclimate shifts drive west Greenland ice cap change. <i>Nature Geoscience 14(10)</i>: 756-761. <a href=\"https://dx.doi.org/10.1038/s41561-021-00818-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00818-w</a>","StandardTitle":"Abrupt Common Era hydroclimate shifts drive west Greenland ice cap change","AuthorsString":"Osman, M.B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":361140,"RR":"<b>Jones, M.M.; Sageman, B.B.; Selby, D.; Jacobson, A.D.; Batenburg, S.J.; Riquier, L.; Macleod, K.G.; Huber, B.T.; Bogus, K.A.; Tejada, M.L.G.; Kuroda, J.; Hobbs, R.W.</b> (2023). Abrupt episode of mid-Cretaceous ocean acidification triggered by massive volcanism. <i>Nature Geoscience 16(2)</i>: 169-174. <a href=\"https://dx.doi.org/10.1038/s41561-022-01115-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01115-w</a>","StandardTitle":"Abrupt episode of mid-Cretaceous ocean acidification triggered by massive volcanism","AuthorsString":"Jones, M.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":391169,"RR":"<b>Grieman, M.M.; Nehrbass-Ahles, C.; Hoffmann, H.M.; Bauska, T.K.; King, A.C.F.; Mulvaney, R.; Rhodes, R.H.; Rowell, I.F.; Thomas, E.R.; Wolff, E.W.</b> (2024). Abrupt Holocene ice loss due to thinning and ungrounding in the Weddell Sea Embayment. <i>Nature Geoscience 17(3)</i>: 227-232. <a href=\"https://dx.doi.org/10.1038/s41561-024-01375-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01375-8</a>","StandardTitle":"Abrupt Holocene ice loss due to thinning and ungrounding in the Weddell Sea Embayment","AuthorsString":"Grieman, M.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":286597,"RR":"<b>Zhang, X.; Knorr, G.; Lohmann, G.; Barker, S.</b> (2017). Abrupt North Atlantic circulation changes in response to gradual CO<sub>2</sub> forcing in a glacial climate state. <i>Nature Geoscience 10(7)</i>: 518-523. <a href=\"https://dx.doi.org/10.1038/ngeo2974\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2974</a>","StandardTitle":"Abrupt North Atlantic circulation changes in response to gradual CO<sub>2</sub> forcing in a glacial climate state","AuthorsString":"Zhang, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":230799,"RR":"<b>Lopes dos Santos, R.A.; De Deckker, P.; Hopmans, E.C.; Magee, J.W.; Mets, A.; Sinninghe Damsté, J.S.; Schouten, S.</b> (2013). Abrupt vegetation change after the Late Quaternary megafaunal extinction in southeastern Australia. <i>Nature Geoscience 6(8)</i>: 627-631. <a href=\"http://dx.doi.org/10.1038/NGEO1856\" target=\"_blank\">dx.doi.org/10.1038/NGEO1856</a>","StandardTitle":"Abrupt vegetation change after the Late Quaternary megafaunal extinction in southeastern Australia","AuthorsString":"Lopes dos Santos, R.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":324017,"RR":"<b>Saito, M.A.; McIlvin, M.R.; Moran, D.M.; Santoro, A.E.; Dupont, C.L.; Rafter, P.A.; Saunders, J.K.; Kaul, D.; Lamborg, C.H.; Westley, M.; Valois, F.; Waterbury, J.B.</b> (2020). Abundant nitrite-oxidizing metalloenzymes in the mesopelagic zone of the tropical Pacific Ocean. <i>Nature Geoscience 13(5)</i>: 355-362. <a href=\"https://dx.doi.org/10.1038/s41561-020-0565-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0565-6</a>","StandardTitle":"Abundant nitrite-oxidizing metalloenzymes in the mesopelagic zone of the tropical Pacific Ocean","AuthorsString":"Saito, M.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":258275,"RR":"<b>Ito, T.; Nenes, A.; Johnson, M.S.; Meskhidze, N.; Deutsch, C.</b> (2016). Acceleration of oxygen decline in the tropical Pacific over the past decades by aerosol pollutants. <i>Nature Geoscience 9(6)</i>: 443-447. <a href=\"http://dx.doi.org/10.1038/ngeo2717\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2717</a>","StandardTitle":"Acceleration of oxygen decline in the tropical Pacific over the past decades by aerosol pollutants","AuthorsString":"Ito, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":294790,"RR":"<b>Sibrant, A.L.R.; Mittelstaedt, E.; Davaille, A.; Pauchard, L.; Aubertin, A.; Auffray, L.; Pidoux, R.</b> (2018). Accretion mode of oceanic ridges governed by axial mechanical strength. <i>Nature Geoscience 11(4)</i>: 274-279. <a href=\"https://dx.doi.org/10.1038/s41561-018-0084-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0084-x</a>","StandardTitle":"Accretion mode of oceanic ridges governed by axial mechanical strength","AuthorsString":"Sibrant, A.L.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":249206,"RR":"<b>Hall, B.L.; Denton, G.H.; Jackson, M.S.; Koffman, T.N.B.</b> (2015). Accumulation and marine forcing of ice dynamics in the western Ross Sea during the last deglaciation. <i>Nature Geoscience 8(8)</i>: 625-628. <a href=\"http://dx.doi.org/10.1038/ngeo2478\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2478</a>","StandardTitle":"Accumulation and marine forcing of ice dynamics in the western Ross Sea during the last deglaciation","AuthorsString":"Hall, B.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":250193,"RR":"<b>Klotzbach, P.; Gray, W.; Fogarty, C.</b> (2015). Active Atlantic hurricane era at its end? <i>Nature Geoscience 8(10)</i>: 737–738. <a href=\"http://dx.doi.org/10.1038/ngeo2529\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2529</a>","StandardTitle":"Active Atlantic hurricane era at its end?","AuthorsString":"Klotzbach, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359515,"RR":"<b>Larkin, C.S.; Ezat, M.M.; Roberts, N.L.; Bauch, H.A.; Spielhagen, R.F.; Noormets, R.; Polyak, L.; Moreton, S.G.; Rasmussen, T.L.; Sarnthein, M.; Tipper, E.T.; Piotrowski, A.M.</b> (2022). Active Nordic Seas deep-water formation during the last glacial maximum. <i>Nature Geoscience 15(11)</i>: 925-931. <a href=\"https://dx.doi.org/10.1038/s41561-022-01050-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01050-w</a>","StandardTitle":"Active Nordic Seas deep-water formation during the last glacial maximum","AuthorsString":"Larkin, C.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":244510,"RR":"<b>Mori, M.; Watanabe, M.; Shiogama, H.; Inoue, J.; Kimoto, M.</b> (2015). Addendum: Robust Arctic sea-ice influence on the frequent Eurasian cold winters in past decades. <i>Nature Geoscience 8(2)</i>: 159. <a href=\"http://dx.doi.org/10.1038/ngeo2348\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2348</a>","StandardTitle":"Addendum: Robust Arctic sea-ice influence on the frequent Eurasian cold winters in past decades","AuthorsString":"Mori, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":247388,"RR":"<b>Crespo-Medina, M.; Meile, C.D.; Hunter, K.S.; Diercks, A.-R.; Asper, V.L.; Orphan, V.J.; Tavormina, P.L.; Nigro, L.M.; Battles, J.J.; Chanton, J.P.; Shiller, A.M.; Joung, D.-J.; Amon, R.M.W.; Bracco, A.; Montoya, J.P.; Villareal, T.A.; Wood, A.M.; Joye, S.B.</b> (2015). Addendum: The rise and fall of methanotrophy following a deepwater oil-well blowout. <i>Nature Geoscience 8(6)</i>: 490. <a href=\"https://dx.doi.org/10.1038/NGEO2447\" target=\"_blank\">https://dx.doi.org/10.1038/NGEO2447</a>","StandardTitle":"Addendum: The rise and fall of methanotrophy following a deepwater oil-well blowout","AuthorsString":"Crespo-Medina, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":356597,"RR":"(2022). Air temperature — not just ocean warming — affects submarine melting of Greenland glaciers. <i>Nature Geoscience 15(10)</i>: 763-764. <a href=\"https://dx.doi.org/10.1038/s41561-022-01036-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01036-8</a>","StandardTitle":"Air temperature — not just ocean warming — affects submarine melting of Greenland glaciers","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":312362,"RR":"<b>Yang, J.; Junium, C.K.; Grassineau, N.V.; Nisbet, E.G.; Izon, G.; Mettam, C.; Zerkle, A.L.</b> (2019). Ammonium availability in the Late Archaean nitrogen cycle. <i>Nature Geoscience 12(7)</i>: 553-557. <a href=\"https://dx.doi.org/10.1038/s41561-019-0371-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0371-1</a>","StandardTitle":"Ammonium availability in the Late Archaean nitrogen cycle","AuthorsString":"Yang, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":252695,"RR":"<b>Rädel, G.; Mauritsen, T.; Stevens, B.; Dommenget, D.; Matei, D.; Bellomo, K.; Clement, A.</b> (2016). Amplification of El Niño by cloud longwave coupling to atmospheric circulation. <i>Nature Geoscience 9(2)</i>: 106-110. <a href=\"http://dx.doi.org/10.1038/ngeo2630\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2630</a>","StandardTitle":"Amplification of El Niño by cloud longwave coupling to atmospheric circulation","AuthorsString":"Rädel, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":347573,"RR":"<b>Byrne, M.P.</b> (2021). Amplified warming of extreme temperatures over tropical land. <i>Nature Geoscience 14(11)</i>: 837-841. <a href=\"https://dx.doi.org/10.1038/s41561-021-00828-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00828-8</a>","StandardTitle":"Amplified warming of extreme temperatures over tropical land","AuthorsString":"Byrne, M.P.","BibLvlCode":"AS"},{"BRefID":260849,"RR":"<b>Penman, D.E.; Turner, S.K.; Sexton, P.F.; Norris, R.D.; Dickson, A.J.; Boulila, S.; Ridgwell, A.J.; Zeebe, R.E.; Zachos, J.C.; Cameron, A.; Westerhold, T.; Röhl, U.</b> (2016). An abyssal carbonate compensation depth overshoot in the aftermath of the Palaeocene–Eocene Thermal Maximum. <i>Nature Geoscience 9(8)</i>: 575-580. <a href=\"http://dx.doi.org/10.1038/ngeo2757\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2757</a>","StandardTitle":"An abyssal carbonate compensation depth overshoot in the aftermath of the Palaeocene–Eocene Thermal Maximum","AuthorsString":"Penman, D.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":294036,"RR":"<b>Parman, S.</b> (2018). An Archaean mushy mantle. <i>Nature Geoscience 11(2)</i>: 85-86. <a href=\"https://dx.doi.org/10.1038/s41561-018-0060-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0060-5</a>","StandardTitle":"An Archaean mushy mantle","AuthorsString":"Parman, S.","BibLvlCode":"AS"},{"BRefID":294035,"RR":"<b>Gomes, M.L.</b> (2018). An Archaean oxygen oasis. <i>Nature Geoscience 11(2)</i>: 84-85. <a href=\"https://dx.doi.org/10.1038/s41561-018-0058-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0058-z</a>","StandardTitle":"An Archaean oxygen oasis","AuthorsString":"Gomes, M.L.","BibLvlCode":"AS"},{"BRefID":395751,"RR":"(2024). An ensemble assessment to improve estimates of land-to-ocean carbon fluxes. <i>Nature Geoscience 17(9)</i>: 829-830. <a href=\"https://dx.doi.org/10.1038/s41561-024-01526-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01526-x</a>","StandardTitle":"An ensemble assessment to improve estimates of land-to-ocean carbon fluxes","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":291296,"RR":"<b>Foley, S.F.; Fischer, T.P.</b> (2017). An essential role for continental rifts and lithosphere in the deep carbon cycle. <i>Nature Geoscience 10(12)</i>: 897-902. <a href=\"https://dx.doi.org/10.1038/s41561-017-0002-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0002-7</a>","StandardTitle":"An essential role for continental rifts and lithosphere in the deep carbon cycle","AuthorsString":"Foley, S.F.; Fischer, T.P.","BibLvlCode":"AS"},{"BRefID":393303,"RR":"(2024). An extended pan-North African humid period within the warm Pliocene. <i>Nature Geoscience 17(7)</i>: 596-597. <a href=\"https://dx.doi.org/10.1038/s41561-024-01481-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01481-7</a>","StandardTitle":"An extended pan-North African humid period within the warm Pliocene","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":312033,"RR":"<b>DeFelice, C.; Mallick, S.; Saal, A.E.; Huang, S.</b> (2019). An isotopically depleted lower mantle component is intrinsic to the Hawaiian mantle plume. <i>Nature Geoscience 12(6)</i>: 487-492. <a href=\"https://dx.doi.org/10.1038/s41561-019-0348-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0348-0</a>","StandardTitle":"An isotopically depleted lower mantle component is intrinsic to the Hawaiian mantle plume","AuthorsString":"DeFelice, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":308749,"RR":"<b>Park, S.-H.; Langmuir, C.H.; Sims, K.W.W.; Blichert-Toft, J.; Kim, S.-S.; Scott, S.R.; Lin, J.; Choi, H.; Yang, Y.-S.; Michael, P.J.</b> (2019). An isotopically distinct Zealandia–Antarctic mantle domain in the Southern Ocean. <i>Nature Geoscience 12(3)</i>: 206-214. <a href=\"https://dx.doi.org/10.1038/s41561-018-0292-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0292-4</a>","StandardTitle":"An isotopically distinct Zealandia–Antarctic mantle domain in the Southern Ocean","AuthorsString":"Park, S.-H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":316667,"RR":"<b>Deng, Z.; Chaussidon, M.; Puchtel, I.S.; Dauphas, N.; Moynier, F.</b> (2019). An oceanic subduction origin for Archaean granitoids revealed by silicon isotopes. <i>Nature Geoscience 12(9)</i>: 774-778. <a href=\"https://dx.doi.org/10.1038/s41561-019-0407-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0407-6</a>","StandardTitle":"An oceanic subduction origin for Archaean granitoids revealed by silicon isotopes","AuthorsString":"Deng, Z. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":439203,"RR":"<b>Lenain, L.; Srinivasan, K.; Barkan, R.; Pizzo, N.</b> (2026). An unprecedented view of ocean currents from geostationary satellites. <i>Nature Geoscience 19(5)</i>: 526-533. <a href=\"https://dx.doi.org/10.1038/s41561-026-01943-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01943-0</a>","StandardTitle":"An unprecedented view of ocean currents from geostationary satellites","AuthorsString":"Lenain, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":345734,"RR":"<b>Märki, L.; Lupker, M.; France-Lanord, C.; Lavé, J.; Gallen, S.; Gajurel, A.P.; Haghipour, N.; Leuenberger-West, F.; Eglinton, T.</b> (2021). An unshakable carbon budget for the Himalaya. <i>Nature Geoscience 14(10)</i>: 745-750. <a href=\"https://dx.doi.org/10.1038/s41561-021-00815-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00815-z</a>","StandardTitle":"An unshakable carbon budget for the Himalaya","AuthorsString":"Märki, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":289160,"RR":"<b>Simkins, L.M.; Anderson, J.B.; Greenwood, S.L.; Gonnermann, H.M.; Prothro, L.O.; Halberstadt, A.R.W.; Stearns, L.A.; Pollard, D.; DeConto, R.M.</b> (2017). Anatomy of a meltwater drainage system beneath the ancestral East Antarctic ice sheet. <i>Nature Geoscience 10(9)</i>: 691-697. <a href=\"https://dx.doi.org/10.1038/ngeo3012\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3012</a>","StandardTitle":"Anatomy of a meltwater drainage system beneath the ancestral East Antarctic ice sheet","AuthorsString":"Simkins, L.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":324014,"RR":"<b>Ortiz, J.D.</b> (2020). Ancient ice-sheet collapse. <i>Nature Geoscience 13(5)</i>: 328-329. <a href=\"https://dx.doi.org/10.1038/s41561-020-0572-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0572-7</a>","StandardTitle":"Ancient ice-sheet collapse","AuthorsString":"Ortiz, J.D.","BibLvlCode":"AS"},{"BRefID":359760,"RR":"<b>Keerthi, M.G.; Prend, C.J.; Aumont, O.; Lévy, M.</b> (2022). Annual variations in phytoplankton biomass driven by small-scale physical processes. <i>Nature Geoscience 15(12)</i>: 1027-1033. <a href=\"https://dx.doi.org/10.1038/s41561-022-01057-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01057-3</a>","StandardTitle":"Annual variations in phytoplankton biomass driven by small-scale physical processes","AuthorsString":"Keerthi, M.G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":294786,"RR":"<b>Bristow, L.A.</b> (2018). Anoxia in the snow. <i>Nature Geoscience 11(4)</i>: 226-227. <a href=\"https://dx.doi.org/10.1038/s41561-018-0088-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0088-6</a>","StandardTitle":"Anoxia in the snow","AuthorsString":"Bristow, L.A.","BibLvlCode":"AS"},{"BRefID":359509,"RR":"<b>Dow, C.F.; Ross, N.; Jeofry, H.; Siu, K.; Siegert, M.J.</b> (2022). Antarctic basal environment shaped by high-pressure flow through a subglacial river system. <i>Nature Geoscience 15(11)</i>: 892-898. <a href=\"https://dx.doi.org/10.1038/s41561-022-01059-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01059-1</a>","StandardTitle":"Antarctic basal environment shaped by high-pressure flow through a subglacial river system","AuthorsString":"Dow, C.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":249210,"RR":"<b>Evans, J.</b> (2015). Antarctic ice growth and retreat. <i>Nature Geoscience 8(8)</i>: 585-586. <a href=\"http://dx.doi.org/10.1038/ngeo2494\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2494</a>","StandardTitle":"Antarctic ice growth and retreat","AuthorsString":"Evans, J.","BibLvlCode":"AS"},{"BRefID":306497,"RR":"<b>Levy, R.H.; Meyers, S.R.; Naish, T.R.; Golledge, N.R.; McKay, R.M.; Crampton, J.S.; DeConto, R.M.; De Santis, L.; Florindo, F.; Gasson, E.G.W.; Harwood, D.M.; Luyendyk, B.P.; Powell, R.D.; Clowes, C.; Kulhanek, D.K.</b> (2019). Antarctic ice-sheet sensitivity to obliquity forcing enhanced through ocean connections. <i>Nature Geoscience 12(2)</i>: 132-137. <a href=\"https://dx.doi.org/10.1038/s41561-018-0284-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0284-4</a>","StandardTitle":"Antarctic ice-sheet sensitivity to obliquity forcing enhanced through ocean connections","AuthorsString":"Levy, R.H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":351959,"RR":"<b>Christie, F.D.W.; Benham, T.J.; Batchelor, C.L.; Rack, W.; Montelli, A.; Dowdeswell, J.A.</b> (2022). Antarctic ice-shelf advance driven by anomalous atmospheric and sea-ice circulation. <i>Nature Geoscience 15(5)</i>: 356-362. <a href=\"https://dx.doi.org/10.1038/s41561-022-00938-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00938-x</a>","StandardTitle":"Antarctic ice-shelf advance driven by anomalous atmospheric and sea-ice circulation","AuthorsString":"Christie, F.D.W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":436571,"RR":"<b>Suganuma, Yusuke; Itaki, Takuya; Haneda, Yuki; Kusahara, Kazuya; Obase, Takashi; Ishiwa, Takeshige; Omori, Takayuki; Ikehara, Minoru; McKay, Robert; Seki, Osamu; Hirano, Daisuke; Fujii, Masakazu; Kato, Yuji; Amano, Atsuko; Tokuda, Yuki; Iwatani, Hokuto; Suzuki, Yoshiaki; Hirabayashi, Motohiro; Matsuzaki, Hiroyuki; Yamagata, Takeyasu; Iwai, Masao; Katsuki, Kota; Jimenez-Espejo, Francisco J.; Matsui, Hiroki; Seike, Koji; Kawamata, Moto; Nishida, Naohisa; Ito, Masato; Sugiyama, Shin; Okuno, Jun’ichi; Sawagaki, Takanobu; Abe-Ouchi, Ayako; Aoki, Shigeru; Miura, Hideki</b> (2025). Antarctic ice-shelf collapse in Holocene driven by meltwater release feedbacks. <i>Nature Geoscience 18(12)</i>: 1216-1223. <a href=\"https://dx.doi.org/10.1038/s41561-025-01829-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01829-7</a>","StandardTitle":"Antarctic ice-shelf collapse in Holocene driven by meltwater release feedbacks","AuthorsString":"Suganuma, Yusuke <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":380817,"RR":"<b>Fox, M.; Clinger, A.; Smith, A.G.G.; Cuffey, K.; Shuster, D.; Herman, F.</b> (2024). Antarctic Peninsula glaciation patterns set by landscape evolution and dynamic topography. <i>Nature Geoscience 17(1)</i>: 73-78. <a href=\"https://dx.doi.org/10.1038/s41561-023-01336-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01336-7</a>","StandardTitle":"Antarctic Peninsula glaciation patterns set by landscape evolution and dynamic topography","AuthorsString":"Fox, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":260850,"RR":"<b>Meehl, G.A.; Arblaster, J.M.; Bitz, C.M.; Chung, C.T.Y.; Teng, H.</b> (2016). Antarctic sea-ice expansion between 2000 and 2014 driven by tropical Pacific decadal climate variability. <i>Nature Geoscience 9(8)</i>: 590-595. <a href=\"http://dx.doi.org/10.1038/ngeo2751\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2751</a>","StandardTitle":"Antarctic sea-ice expansion between 2000 and 2014 driven by tropical Pacific decadal climate variability","AuthorsString":"Meehl, G.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":240938,"RR":"<b>Rohling, E.J.; Grant, K.; Bolshaw, M.; Roberts, A.P.; Siddall, M.; Hemleben, Ch.; Kucera, M.</b> (2009). Antarctic temperature and global sea level closely coupled over the past five glacial cycles. <i>Nature Geoscience 2(7)</i>: 500-504. <a href=\"http://dx.doi.org/10.1038/ngeo557\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo557</a>","StandardTitle":"Antarctic temperature and global sea level closely coupled over the past five glacial cycles","AuthorsString":"Rohling, E.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":301859,"RR":"<b>Studinger, M.; Barrett, P.</b> (2009). Antarctica sinking. <i>Nature Geoscience 2(10)</i>: 671-672. <a href=\"https://dx.doi.org/10.1038/ngeo644\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo644</a>","StandardTitle":"Antarctica sinking","AuthorsString":"Studinger, M.; Barrett, P.","BibLvlCode":"AS"},{"BRefID":391793,"RR":"<b>Bianchi, T.S.; Mayer, L.M.; Amaral, J.H.F.; Arndt, S.; Galy, V.; Kemp, D.B.; Kuehl, S.A.; Murray, N.J.; Regnier, P.</b> (2024). Anthropogenic impacts on mud and organic carbon cycling. <i>Nature Geoscience 17(4)</i>: 287-297. <a href=\"https://dx.doi.org/10.1038/s41561-024-01405-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01405-5</a>","StandardTitle":"Anthropogenic impacts on mud and organic carbon cycling","AuthorsString":"Bianchi, T.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":230798,"RR":"<b>Regnier, P.; Friedlingstein, P.; Ciais, P.; Mackenzie, F.T.; Gruber, N.; Janssens, I.A.; Laruelle, G.G.; Lauerwald, R.; Luyssaert, S.; Andersson, A.J.; Arndt, S.; Arnosti, C.; Borges, A.V.; Dale, A.W.; Gallego-Sala, A.; Godderis, Y.; Goossens, N.; Hartmann, J.; Heinze, C.; Ilyina, T.; Joos, F.; LaRowe, D.E.; Leifeld, J.; Meysman, F.J.R.; Munhoven, G.; Raymond, P.A.; Spahni, R.; Suntharalingam, P.; Thullner, M.</b> (2013). Anthropogenic perturbation of the carbon fluxes from land to ocean. <i>Nature Geoscience 6(8)</i>: 597-607. <a href=\"http://dx.doi.org/10.1038/NGEO1830\" target=\"_blank\">dx.doi.org/10.1038/NGEO1830</a>","StandardTitle":"Anthropogenic perturbation of the carbon fluxes from land to ocean","AuthorsString":"Regnier, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":306501,"RR":"<b>Best, J.</b> (2019). Anthropogenic stresses on the world’s big rivers. <i>Nature Geoscience 12(1)</i>: 7-21. <a href=\"https://dx.doi.org/10.1038/s41561-018-0262-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0262-x</a>","StandardTitle":"Anthropogenic stresses on the world’s big rivers","AuthorsString":"Best, J.","BibLvlCode":"AS"},{"BRefID":313849,"RR":"<b>Tollan, P.; Hermann, J.</b> (2019). Arc magmas oxidized by water dissociation and hydrogen incorporation in orthopyroxene. <i>Nature Geoscience 12(8)</i>: 667-671. <a href=\"https://dx.doi.org/10.1038/s41561-019-0411-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0411-x</a>","StandardTitle":"Arc magmas oxidized by water dissociation and hydrogen incorporation in orthopyroxene","AuthorsString":"Tollan, P.; Hermann, J.","BibLvlCode":"AS"},{"BRefID":298400,"RR":"<b>Calvert, A.J.; Doublier, M.P.</b> (2018). Archaean continental spreading inferred from seismic images of the Yilgarn Craton. <i>Nature Geoscience 11(7)</i>: 526-530. <a href=\"https://dx.doi.org/10.1038/s41561-018-0138-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0138-0</a>","StandardTitle":"Archaean continental spreading inferred from seismic images of the Yilgarn Craton","AuthorsString":"Calvert, A.J.; Doublier, M.P.","BibLvlCode":"AS"},{"BRefID":408010,"RR":"<b>Cañadas, F.; Guilbaud, R.; Fralick, P.; Xiong, Y.; Poulton, S.W.; Martin-Redondo, M.-P.; Fairén, A.G.</b> (2025). Archaean oxygen oases driven by pulses of enhanced phosphorus recycling in the ocean. <i>Nature Geoscience 18(5)</i>: 430-435. <a href=\"https://dx.doi.org/10.1038/s41561-025-01678-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01678-4</a>","StandardTitle":"Archaean oxygen oases driven by pulses of enhanced phosphorus recycling in the ocean","AuthorsString":"Cañadas, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":332654,"RR":"<b>Rosas, J.C.; Korenaga, J.</b> (2021). Archaean seafloors shallowed with age due to radiogenic heating in the mantle. <i>Nature Geoscience 14(1)</i>: 51-56. <a href=\"https://dx.doi.org/10.1038/s41561-020-00673-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00673-1</a>","StandardTitle":"Archaean seafloors shallowed with age due to radiogenic heating in the mantle","AuthorsString":"Rosas, J.C.; Korenaga, J.","BibLvlCode":"AS"},{"BRefID":419031,"RR":"<b>Kim, B.; Zhang, Y.G.; Zeebe, R.E.; Shen, J.</b> (2025). Arctic CO<sub>2</sub> emissions amplified by aerobic methane oxidation during the Palaeocene–Eocene Thermal Maximum. <i>Nature Geoscience 18(10)</i>: 975-982. <a href=\"https://dx.doi.org/10.1038/s41561-025-01784-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01784-3</a>","StandardTitle":"Arctic CO<sub>2</sub> emissions amplified by aerobic methane oxidation during the Palaeocene–Eocene Thermal Maximum","AuthorsString":"Kim, B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":330011,"RR":"<b>McCarty, J.L.; Smith, T.E.L.; Turetsky, M.R.</b> (2020). Arctic fires re-emerging. <i>Nature Geoscience 13(10)</i>: 658-660. <a href=\"https://dx.doi.org/10.1038/s41561-020-00645-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00645-5</a>","StandardTitle":"Arctic fires re-emerging","AuthorsString":"McCarty, J.L.; Smith, T.E.L.; Turetsky, M.R.","BibLvlCode":"AS"},{"BRefID":404836,"RR":"<b>Wang, Q.; Danilov, S.; Jung, T.</b> (2024). Arctic freshwater anomaly transiting to the North Atlantic delayed within a buffer zone. <i>Nature Geoscience 17(12)</i>: 1218-1221. <a href=\"https://dx.doi.org/10.1038/s41561-024-01592-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01592-1</a>","StandardTitle":"Arctic freshwater anomaly transiting to the North Atlantic delayed within a buffer zone","AuthorsString":"Wang, Q.; Danilov, S.; Jung, T.","BibLvlCode":"AS"},{"BRefID":364414,"RR":"<b>Segato, D.; Saiz-Lopez, A.; Mahajan, A.S.; Wang, F.; Corella, J.P.; Cuevas, C.A.; Erhardt, T.; Jensen, C.M.; Zeppenfeld, C.; Kjær, H.A.; Turetta, C.; Cairns, W.R.E.; Barbante, C.; Spolaor, A.</b> (2023). Arctic mercury flux increased through the Last Glacial Termination with a warming climate. <i>Nature Geoscience 16(5)</i>: 439-445. <a href=\"https://dx.doi.org/10.1038/s41561-023-01172-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01172-9</a>","StandardTitle":"Arctic mercury flux increased through the Last Glacial Termination with a warming climate","AuthorsString":"Segato, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":344779,"RR":"<b>Farmer, J.R.; Sigman, D.M.; Granger, J.; Underwood, O.M.; Fripiat, F.; Cronin, T.M.; Martínez-Garcia, A.; Haug, G.H.</b> (2021). Arctic Ocean stratification set by sea level and freshwater inputs since the last ice age. <i>Nature Geoscience 14(9)</i>: 684-689. <a href=\"https://dx.doi.org/10.1038/s41561-021-00789-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00789-y</a>","StandardTitle":"Arctic Ocean stratification set by sea level and freshwater inputs since the last ice age","AuthorsString":"Farmer, J.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":354970,"RR":"<b>Kohler, S.G.; Heimbürger-Boavida, L.-E.; Petrova, M.V.; Digernes, M.G.; Sanchez, N.; Dufour, A.; Simic, A.; Ndungu, K.; Ardelan, M.V.</b> (2022). Arctic Ocean’s wintertime mercury concentrations limited by seasonal loss on the shelf. <i>Nature Geoscience 15(8)</i>: 621-626. <a href=\"https://dx.doi.org/10.1038/s41561-022-00986-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00986-3</a>","StandardTitle":"Arctic Ocean’s wintertime mercury concentrations limited by seasonal loss on the shelf","AuthorsString":"Kohler, S.G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366508,"RR":"<b>Lacroix, F.</b> (2023). Arctic rivers tell tales of change. <i>Nature Geoscience 16(9)</i>: 760-761. <a href=\"https://dx.doi.org/10.1038/s41561-023-01248-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01248-6</a>","StandardTitle":"Arctic rivers tell tales of change","AuthorsString":"Lacroix, F.","BibLvlCode":"AS"},{"BRefID":245581,"RR":"<b>Lique, C.</b> (2015). Arctic sea ice heated from below. <i>Nature Geoscience 8(3)</i>: 172–173. <a href=\"http://dx.doi.org/10.1038/ngeo2357\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2357</a>","StandardTitle":"Arctic sea ice heated from below","AuthorsString":"Lique, C.","BibLvlCode":"AS"},{"BRefID":337171,"RR":"<b>Bailey, H.; Hubbard, A.; Klein, E.S.; Mustonen, K.R.; Akers, P.D.; Marttila, H.; Welker, J.M.</b> (2021). Arctic sea-ice loss fuels extreme European snowfall. <i>Nature Geoscience 14(5)</i>: 283-288. <a href=\"https://hdl.handle.net/10.1038/s41561-021-00719-y\" target=\"_blank\">https://hdl.handle.net/10.1038/s41561-021-00719-y</a>","StandardTitle":"Arctic sea-ice loss fuels extreme European snowfall","AuthorsString":"Bailey, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":311929,"RR":"<b>Olonscheck, D.; Mauritsen, T.; Notz, D.</b> (2019). Arctic sea-ice variability is primarily driven by atmospheric temperature fluctuations. <i>Nature Geoscience 12(6)</i>: 430-434. <a href=\"https://dx.doi.org/10.1038/s41561-019-0363-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0363-1</a>","StandardTitle":"Arctic sea-ice variability is primarily driven by atmospheric temperature fluctuations","AuthorsString":"Olonscheck, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296258,"RR":"<b>Docherty, C.L.</b> (2018). Arctic streams in murky waters. <i>Nature Geoscience 11(5)</i>: 304-304. <a href=\"https://dx.doi.org/10.1038/s41561-018-0115-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0115-7</a>","StandardTitle":"Arctic streams in murky waters","AuthorsString":"Docherty, C.L.","BibLvlCode":"AS"},{"BRefID":366720,"RR":"<b>Gong, X.; Zhang, J.; Croft, B.; Yang, X.; Frey, M.M.; Bergner, N.; Chang, R.Y.-W.; Creamean, J.M.; Kuang, C.; Martin, R.V.; Ranjithkumar, A.; Sedlacek, A.J.; Uin, J.; Willmes, S.; Zawadowicz, M.A.; Pierce, J.R.; Shupe, M.D.; Schmale, J.; Wang, J.</b> (2023). Arctic warming by abundant fine sea salt aerosols from blowing snow. <i>Nature Geoscience 16(9)</i>: 768-774. <a href=\"https://dx.doi.org/10.1038/s41561-023-01254-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01254-8</a>","StandardTitle":"Arctic warming by abundant fine sea salt aerosols from blowing snow","AuthorsString":"Gong, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":324982,"RR":"<b>Kadow, C.; Hall, D.M.; Ulbrich, U.</b> (2020). Artificial intelligence reconstructs missing climate information. <i>Nature Geoscience 13(6)</i>: 408-413. <a href=\"https://dx.doi.org/10.1038/s41561-020-0582-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0582-5</a>","StandardTitle":"Artificial intelligence reconstructs missing climate information","AuthorsString":"Kadow, C.; Hall, D.M.; Ulbrich, U.","BibLvlCode":"AS"},{"BRefID":361143,"RR":"<b>Hua, J.; Fischer, K.M.; Becker, T.W.; Gazel, E.; Hirth, G.</b> (2023). Asthenospheric low-velocity zone consistent with globally prevalent partial melting. <i>Nature Geoscience 16(2)</i>: 175-181. <a href=\"https://dx.doi.org/10.1038/s41561-022-01116-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01116-9</a>","StandardTitle":"Asthenospheric low-velocity zone consistent with globally prevalent partial melting","AuthorsString":"Hua, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":354975,"RR":"<b>Crocker, A.J.; Naafs, B.D.A.; Westerhold, T.; James, R.H.; Cooper, M.J.; Röhl, U.; Pancost, R.D.; Xuan, C.; Osborne, C.P.; Beerling, D.J.; Wilson, P.A.</b> (2022). Astronomically controlled aridity in the Sahara since at least 11 million years ago. <i>Nature Geoscience 15(8)</i>: 671-676. <a href=\"https://dx.doi.org/10.1038/s41561-022-00990-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00990-7</a>","StandardTitle":"Astronomically controlled aridity in the Sahara since at least 11 million years ago","AuthorsString":"Crocker, A.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":351413,"RR":"<b>Roach, L.A.; Eisenman, I.; Wagner, T.J.W.; Blanchard-Wrigglesworth, E.; Bitz, C.M.</b> (2022). Asymmetry in the seasonal cycle of Antarctic sea ice driven by insolation. <i>Nature Geoscience 15(4)</i>: 277-281. <a href=\"https://dx.doi.org/10.1038/s41561-022-00913-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00913-6</a>","StandardTitle":"Asymmetry in the seasonal cycle of Antarctic sea ice driven by insolation","AuthorsString":"Roach, L.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":332652,"RR":"<b>Meehl, G.A.; Hu, A.; Castruccio, F.; England, M.H.; Bates, S.C.; Danabasoglu, G.; McGregor, S.; Arblaster, J.M.; Xie, S.-P.; Rosenbloom, N.</b> (2021). Atlantic and Pacific tropics connected by mutually interactive decadal-timescale processes. <i>Nature Geoscience 14(1)</i>: 36-42. <a href=\"https://dx.doi.org/10.1038/s41561-020-00669-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00669-x</a>","StandardTitle":"Atlantic and Pacific tropics connected by mutually interactive decadal-timescale processes","AuthorsString":"Meehl, G.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":350633,"RR":"<b>Kilbourne, K.H.; Wanamaker, A.D.; Moffa-Sanchez, P.; Reynolds, D.J.; Amrhein, D.E.; Butler, P.G.; Gebbie, G.; Goes, M.; Jansen, M.F.; Little, C.M.; Mette, M.; Moreno-Chamarro, E.; Ortega, P.; Otto-Bliesner, B.L.; Rossby, T.; Scourse, J.; Whitney, N.M.</b> (2022). Atlantic circulation change still uncertain. <i>Nature Geoscience 15</i>: 165-167. <a href=\"https://dx.doi.org/10.1038/s41561-022-00896-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00896-4</a>","StandardTitle":"Atlantic circulation change still uncertain","AuthorsString":"Kilbourne, K.H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":337168,"RR":"<b>Brandt, P.; Hahn, J.; Schmidtko, S.; Tuchen, F.P.; Kopte, R.; Kiko, R.; Bourles, B.; Czeschel, R.; Dengler, M.</b> (2021). Atlantic Equatorial Undercurrent intensification counteracts warming-induced deoxygenation. <i>Nature Geoscience 14(5)</i>: 278-282. <a href=\"https://hdl.handle.net/10.1038/s41561-021-00716-1\" target=\"_blank\">https://hdl.handle.net/10.1038/s41561-021-00716-1</a>","StandardTitle":"Atlantic Equatorial Undercurrent intensification counteracts warming-induced deoxygenation","AuthorsString":"Brandt, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":242733,"RR":"<b>Glessmer, M.S.; Eldevik, T.; Våge, K.; Nilsen, J.E.Ø.; Behrens, E.</b> (2014). Atlantic origin of observed and modelled freshwater anomalies in the Nordic Seas. <i>Nature Geoscience 7(11)</i>: 801–805. <a href=\"http://dx.doi.org/10.1038/ngeo2259\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2259</a>","StandardTitle":"Atlantic origin of observed and modelled freshwater anomalies in the Nordic Seas","AuthorsString":"Glessmer, M.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":363731,"RR":"<b>Zhang, Z.; Jansen, E.; Sobolowski, S.P.; Otterå, O.H.; Ramstein, G.; Guo, C.; Nummelin, A.; Bentsen, M.; Dong, C.; Wang, X.; Wang, H.; Guo, Z.</b> (2023). Atmospheric and oceanic circulation altered by global mean sea-level rise. <i>Nature Geoscience 16(4)</i>: 321-327. <a href=\"https://dx.doi.org/10.1038/s41561-023-01153-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01153-y</a>","StandardTitle":"Atmospheric and oceanic circulation altered by global mean sea-level rise","AuthorsString":"Zhang, Z. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":351418,"RR":"<b>Vettoretti, G.; Ditlevsen, P.; Jochum, M.; Rasmussen, S.O.</b> (2022). Atmospheric CO<sub>2</sub> control of spontaneous millennial-scale ice age climate oscillations. <i>Nature Geoscience 15(4)</i>: 300-306. <a href=\"https://dx.doi.org/10.1038/s41561-022-00920-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00920-7</a>","StandardTitle":"Atmospheric CO<sub>2</sub> control of spontaneous millennial-scale ice age climate oscillations","AuthorsString":"Vettoretti, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":371763,"RR":"<b>Riddell-Young, B.; Rosen, J.; Brook, E.; Buizert, C.; Martin, K.; Lee, J.; Edwards, J.; Mühl, M.; Schmitt, J.; Fischer, H.; Blunier, T.</b> (2023). Atmospheric methane variability through the Last Glacial Maximum and deglaciation mainly controlled by tropical sources. <i>Nature Geoscience 16(12)</i>: 1174-1180. <a href=\"https://dx.doi.org/10.1038/s41561-023-01332-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01332-x</a>","StandardTitle":"Atmospheric methane variability through the Last Glacial Maximum and deglaciation mainly controlled by tropical sources","AuthorsString":"Riddell-Young, B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":439204,"RR":"<b>Jin, Y.; Stephens, B.B.; Long, M.C.; Manizza, M.; Lovenduski, N.S.; Nevison, C.; Morgan, E.J.; Keeling, R.F.</b> (2026). Atmospheric oxygen constraints on Southern Ocean productivity and drivers of carbon uptake. <i>Nature Geoscience 19(5)</i>: 534-541. <a href=\"https://dx.doi.org/10.1038/s41561-026-01944-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01944-z</a>","StandardTitle":"Atmospheric oxygen constraints on Southern Ocean productivity and drivers of carbon uptake","AuthorsString":"Jin, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":310822,"RR":"<b>Allen, S.; Allen, D.; Phoenix, V.R.; Le Roux, G.; Durántez Jiménez, P.; Simonneau, A.; Binet, S.; Galop, D.</b> (2019). Atmospheric transport and deposition of microplastics in a remote mountain catchment. <i>Nature Geoscience 12(5)</i>: 339-344. <a href=\"https://dx.doi.org/10.1038/s41561-019-0335-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0335-5</a>","StandardTitle":"Atmospheric transport and deposition of microplastics in a remote mountain catchment","AuthorsString":"Allen, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":349096,"RR":"<b>Grant, Luke; Vanderkelen, Inne; Gudmundsson, Lukas; Tan, Zeli; Perroud, Marjorie; Stepanenko, Victor M.; Debolskiy, Andrey V.; Droppers, Bram; Janssen, Annette B. G.; Woolway, R. Iestyn; Choulga, Margarita; Balsamo, Gianpaolo; Kirillin, Georgiy; Schewe, Jacob; Zhao, Fang; del Valle, Iliusi Vega; Golub, Malgorzata; Pierson, Don; Marcé, Rafael; Seneviratne, Sonia I.; Thiery, Wim</b> (2021). Attribution of global lake systems change to anthropogenic forcing. <i>Nature Geoscience 14(11)</i>: 849-854. <a href=\"https://dx.doi.org/10.1038/s41561-021-00833-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00833-x</a>","StandardTitle":"Attribution of global lake systems change to anthropogenic forcing","AuthorsString":"Grant, Luke <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":318159,"RR":"<b>Lim, E.-P.; Hendon, H.H.; Boschat, G.; Hudson, D.; Thompson, D.W.J.; Dowdy, A.J.; Arblaster, J.M.</b> (2019). Australian hot and dry extremes induced by weakenings of the stratospheric polar vortex. <i>Nature Geoscience 12(11)</i>: 896-901. <a href=\"https://dx.doi.org/10.1038/s41561-019-0456-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0456-x</a>","StandardTitle":"Australian hot and dry extremes induced by weakenings of the stratospheric polar vortex","AuthorsString":"Lim, E.-P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":349095,"RR":"<b>Grant, Luke; Vanderkelen, Inne; Gudmundsson, Lukas; Tan, Zeli; Perroud, Marjorie; Stepanenko, Victor M.; Debolskiy, Andrey V.; Droppers, Bram; Janssen, Annette B. G.; Woolway, R. Iestyn; Choulga, Margarita; Balsamo, Gianpaolo; Kirillin, Georgiy; Schewe, Jacob; Zhao, Fang; del Valle, Iliusi Vega; Golub, Malgorzata; Pierson, Don; Marcé, Rafael; Seneviratne, Sonia I.; Thiery, Wim</b> (2022). Author Correction: Attribution of global lake systems change to anthropogenic forcing. <i>Nature Geoscience 15(1)</i>: 91-91. <a href=\"https://dx.doi.org/10.1038/s41561-021-00866-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00866-2</a>","StandardTitle":"Author Correction: Attribution of global lake systems change to anthropogenic forcing","AuthorsString":"Grant, Luke <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":362314,"RR":"<b>Hawkings, J.R.; Linhoff, B.S.; Wadham, J.L.; Stibal, M.; Lamborg, C.H.; Carling, G.T.; Lamarche-Gagnon, G.; Kohler, T.J.; Ward, R.; Hendry, K.R.; Falteisek, L.; Kellerman, A.M.; Cameron, K.A.; Hatton, J.E.; Tingey, S.; Holt, A.D.; Vinšová, P.; Hofer, S.; Bulínová, M.; Větrovský, T.; Meire, L.; Spencer, R.G.M.</b> (2021). Author Correction: Large subglacial source of mercury from the southwestern margin of the Greenland Ice Sheet. <i>Nature Geoscience 14(8)</i>: 631-631. <a href=\"https://dx.doi.org/10.1038/s41561-021-00804-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00804-2</a>","StandardTitle":"Author Correction: Large subglacial source of mercury from the southwestern margin of the Greenland Ice Sheet","AuthorsString":"Hawkings, J.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":348085,"RR":"<b>Liu, M.; Zhang, Q.; Maavara, T.; Liu, S.; Wang, X.; Raymond, P.A.</b> (2021). Author Correction: Rivers as the largest source of mercury to coastal oceans worldwide. <i>Nature Geoscience 14(12)</i>: 956-956. <a href=\"https://dx.doi.org/10.1038/s41561-021-00839-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00839-5</a>","StandardTitle":"Author Correction: Rivers as the largest source of mercury to coastal oceans worldwide","AuthorsString":"Liu, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":238944,"RR":"<b>Solomon, E.A.</b> (2014). Bacterial bloom and crash. <i>Nature Geoscience 7(6)</i>: 394 - 395. <a href=\"http://dx.doi.org/10.1038/ngeo2174\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2174</a>","StandardTitle":"Bacterial bloom and crash","AuthorsString":"Solomon, E.A.","BibLvlCode":"AS"},{"BRefID":248293,"RR":"<b>Bargiela, R.; Mapelli, F.; Rojo, D.; Chouaia, B.; Tornés, J.; Borin, S.; Richter, M.; Del Pozo, M.V.; Cappello, S.; Gertier, C.; Genovese, M.; Denaro, R.; Martínez-Martínez, M.; Fodelianakis, S.; Amer, R.A.; Bigazzi, D.; Han, X.; Chen, J.; Chernikova, T.N.; Golyshina, O.V.</b> (2015). Bacterial population and biodegradation potential in chronically crude oil-contaminated marine sediments are strongly linked to temperature. <i>Nature Geoscience 5(11651)</i>: 15 pp. <a href=\"http://dx.doi.org/10.1038/srep11651\" target=\"_blank\">http://dx.doi.org/10.1038/srep11651</a>","StandardTitle":"Bacterial population and biodegradation potential in chronically crude oil-contaminated marine sediments are strongly linked to temperature","AuthorsString":"Bargiela, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":303732,"RR":"<b>Axen, G.J.; van Wijk, J.W.; Currie, C.A.</b> (2018). Basal continental mantle lithosphere displaced by flat-slab subduction. <i>Nature Geoscience 11(12)</i>: 961-964. <a href=\"https://dx.doi.org/10.1038/s41561-018-0263-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0263-9</a>","StandardTitle":"Basal continental mantle lithosphere displaced by flat-slab subduction","AuthorsString":"Axen, G.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":311930,"RR":"<b>Stewart, C.L.; Christoffersen, P.; Nicholls, K.W.; Williams, M.J.M.; Dowdeswell, J.A.</b> (2019). Basal melting of Ross Ice Shelf from solar heat absorption in an ice-front polynya. <i>Nature Geoscience 12(6)</i>: 435-440. <a href=\"https://dx.doi.org/10.1038/s41561-019-0356-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0356-0</a>","StandardTitle":"Basal melting of Ross Ice Shelf from solar heat absorption in an ice-front polynya","AuthorsString":"Stewart, C.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":352879,"RR":"<b>Messié, M.; Petrenko, A.; Doglioli, A.M.; Martinez, E.; Alvain, S.</b> (2022). Basin-scale biogeochemical and ecological impacts of islands in the tropical Pacific Ocean. <i>Nature Geoscience 15(6)</i>: 469-474. <a href=\"https://dx.doi.org/10.1038/s41561-022-00957-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00957-8</a>","StandardTitle":"Basin-scale biogeochemical and ecological impacts of islands in the tropical Pacific Ocean","AuthorsString":"Messié, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":321959,"RR":"<b>Schaffer, J.; Kanzow, T.; von Appen, W.-J.; von Albedyll, L.; Arndt, J.E.; Roberts, D.H.</b> (2020). Bathymetry constrains ocean heat supply to Greenland’s largest glacier tongue. <i>Nature Geoscience 13(3)</i>: 227-231. <a href=\"https://dx.doi.org/10.1038/s41561-019-0529-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0529-x</a>","StandardTitle":"Bathymetry constrains ocean heat supply to Greenland’s largest glacier tongue","AuthorsString":"Schaffer, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":336526,"RR":"<b>Wan, J.; Tokunaga, T.K.; Brown, W.; Newman, A.W.; Dong, W.; Bill, M.; Beutler, C.A.; Henderson, A.N.; Harvey-Costello, N.; Conrad, M.E.; Bouskill, N.J.; Hubbard, S.S.; Williams, K.H.</b> (2021). Bedrock weathering contributes to subsurface reactive nitrogen and nitrous oxide emissions. <i>Nature Geoscience 14(4)</i>: 217-224. <a href=\"https://dx.doi.org/10.1038/s41561-021-00717-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00717-0</a>","StandardTitle":"Bedrock weathering contributes to subsurface reactive nitrogen and nitrous oxide emissions","AuthorsString":"Wan, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366743,"RR":"<b>Shackleton, S.; Seltzer, A.; Baggenstos, D.; Lisiecki, L.E.</b> (2023). Benthic δ<sup>18</sup>O records Earth’s energy imbalance. <i>Nature Geoscience 16(9)</i>: 797-802. <a href=\"https://dx.doi.org/10.1038/s41561-023-01250-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01250-y</a>","StandardTitle":"Benthic δ<sup>18</sup>O records Earth’s energy imbalance","AuthorsString":"Shackleton, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":330717,"RR":"(2020). Between a cloud and a hot place. <i>Nature Geoscience 13(11)</i>: 713-713. <a href=\"https://dx.doi.org/10.1038/s41561-020-00658-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00658-0</a>","StandardTitle":"Between a cloud and a hot place","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":289761,"RR":"<b>Knutti, R.; Rugenstein, M.A.A.; Hegerl, G.C.</b> (2017). Beyond equilibrium climate sensitivity. <i>Nature Geoscience 10(10)</i>: 727-736. <a href=\"https://dx.doi.org/10.1038/ngeo3017\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3017</a>","StandardTitle":"Beyond equilibrium climate sensitivity","AuthorsString":"Knutti, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":341598,"RR":"<b>Anguelova, M.D.</b> (2021). Big potential for tiny droplets. <i>Nature Geoscience 14(8)</i>: 543-544. <a href=\"https://dx.doi.org/10.1038/s41561-021-00801-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00801-5</a>","StandardTitle":"Big potential for tiny droplets","AuthorsString":"Anguelova, M.D.","BibLvlCode":"AS"},{"BRefID":306495,"RR":"<b>González-Gaya, B.; Martínez-Varela, A.; Vila-Costa, M.; Casale, P.; Cerro-Gálvez, E.; Berrojalbiz, N.; Lundin, D.; Vidal, M.; Mompeán, C.; Bode, A.; Jiménez, B.; Dachs, J.</b> (2019). Biodegradation as an important sink of aromatic hydrocarbons in the oceans. <i>Nature Geoscience 12(2)</i>: 119-125. <a href=\"https://dx.doi.org/10.1038/s41561-018-0285-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0285-3</a>","StandardTitle":"Biodegradation as an important sink of aromatic hydrocarbons in the oceans","AuthorsString":"González-Gaya, B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":286592,"RR":"<b>Van Dover, C.L.; Ardron, J.A.; Escobar, E.; Gianni, M.; Gjerde, K.M.; Jaeckel, A.; Jones, D.O.B.; Levin, L.A.; Niner, H.J.; Pendleton, L.; Smith, C.R.; Thiele, T.; Turner, P.J.; Watling, L.; Weaver, P.P.E.</b> (2017). Biodiversity loss from deep-sea mining. <i>Nature Geoscience 10(7)</i>: 464-465. <a href=\"https://dx.doi.org/10.1038/ngeo2983\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2983</a>","StandardTitle":"Biodiversity loss from deep-sea mining","AuthorsString":"Van Dover, C.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":243211,"RR":"<b>Sambrotto, R.N.</b> (2004). Biogeochemical regimes in focus. <i>Nature Geoscience 7(12)</i>: 862–863. <a href=\"http://dx.doi.org/10.1038/ngeo2309\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2309</a>","StandardTitle":"Biogeochemical regimes in focus","AuthorsString":"Sambrotto, R.N.","BibLvlCode":"AS"},{"BRefID":367812,"RR":"<b>Mahmoudi, N.; Steen, A.D.; Halverson, G.P.; Konhauser, K.O.</b> (2023). Biogeochemistry of Earth before exoenzymes. <i>Nature Geoscience 16(10)</i>: 845-850. <a href=\"https://dx.doi.org/10.1038/s41561-023-01266-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01266-4</a>","StandardTitle":"Biogeochemistry of Earth before exoenzymes","AuthorsString":"Mahmoudi, N. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":242288,"RR":"<b>Meysman, F.J.R.</b> (2014). Biogeochemistry: Oxygen burrowed away. <i>Nature Geoscience 7</i>: 620-621. <a href=\"http://dx.doi.org/10.1038/ngeo2218\" target=\"_blank\">dx.doi.org/10.1038/ngeo2218</a>","StandardTitle":"Biogeochemistry: Oxygen burrowed away","AuthorsString":"Meysman, F.J.R.","BibLvlCode":"AS"},{"BRefID":290724,"RR":"<b>Kiko, R.; Biastoch, A.; Brandt, P.; Cravatte, S.; Hauss, H.; Hummels, R.; Kriest, I.; Marin, F.; McDonnell, A.M.P.; Oschlies, A.; Picheral, M.; Schwarzkopf, F.U.; Thurnherr, A.M.; Stemmann, L.</b> (2017). Biological and physical influences on marine snowfall at the equator. <i>Nature Geoscience 10(11)</i>: 852-858. <a href=\"https://dx.doi.org/10.1038/ngeo3042\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3042</a>","StandardTitle":"Biological and physical influences on marine snowfall at the equator","AuthorsString":"Kiko, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":330721,"RR":"<b>Shiozaki, T.; Fujiwara, A.; Inomura, K.; Hirose, Y.; Hashihama, F.; Harada, N.</b> (2020). Biological nitrogen fixation detected under Antarctic sea ice. <i>Nature Geoscience 13(11)</i>: 729-732. <a href=\"https://dx.doi.org/10.1038/s41561-020-00651-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00651-7</a>","StandardTitle":"Biological nitrogen fixation detected under Antarctic sea ice","AuthorsString":"Shiozaki, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":283774,"RR":"<b>Boyd, P.W.; Ellwood, M.J.; Tagliabue, A.; Twining, B.S.</b> (2017). Biotic and abiotic retention, recycling and remineralization of metals in the ocean. <i>Nature Geoscience 10(3)</i>: 167-173. <a href=\"http://dx.doi.org/10.1038/ngeo2876\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2876</a>","StandardTitle":"Biotic and abiotic retention, recycling and remineralization of metals in the ocean","AuthorsString":"Boyd, P.W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":345754,"RR":"<b>Feuillet, Nathalie; Jorry, Stephan; Crawford, Wayne C.; Deplus, Christine; Thinon, Isabelle; Jacques, Eric; Saurel, Jean Marie; Lemoine, Anne; Paquet, Fabien; Satriano, Claudio; Aiken, Chastity; Foix, Océane; Kowalski, Philippe; Laurent, Angèle; Rinnert, Emmanuel; Cathalot, Cécile; Donval, Jean-Pierre; Guyader, Vivien; Gaillot, Arnaud; Scalabrin, Carla; Moreira, Manuel; Peltier, Aline; Beauducel, François; Grandin, Raphaël; Ballu, Valérie; Daniel, Romuald; Pelleau, Pascal; Gomez, Jérémy; Besançon, Simon; Geli, Louis; Bernard, Pascal; Bachelery, Patrick; Fouquet, Yves; Bertil, Didier; Lemarchand, Arnaud; Van der Woerd, Jérome</b> (2021). Birth of a large volcanic edifice offshore Mayotte via lithosphere-scale dyke intrusion. <i>Nature Geoscience 14(10)</i>: 787-795. <a href=\"https://dx.doi.org/10.1038/s41561-021-00809-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00809-x</a>","StandardTitle":"Birth of a large volcanic edifice offshore Mayotte via lithosphere-scale dyke intrusion","AuthorsString":"Feuillet, Nathalie <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366722,"RR":"<b>Jaeglé, L.</b> (2023). Blowing hot and cold. <i>Nature Geoscience 16(9)</i>: 756. <a href=\"https://dx.doi.org/10.1038/s41561-023-01261-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01261-9</a>","StandardTitle":"Blowing hot and cold","AuthorsString":"Jaeglé, L.","BibLvlCode":"AS"},{"BRefID":249476,"RR":"<b>Foreman, B.Z.; Lai, S.Y.J.; Komatsu, Y.; Paola, C.</b> (2015). Braiding of submarine channels controlled by aspect ratio similar to rivers. <i>Nature Geoscience 8(9)</i>: 700–703. <a href=\"http://dx.doi.org/10.1038/ngeo2505\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2505</a>","StandardTitle":"Braiding of submarine channels controlled by aspect ratio similar to rivers","AuthorsString":"Foreman, B.Z. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":411057,"RR":"<b>Wang, F.; Wang, L.; Fei, H.; Miyajima, N.; McCammon, C.; Frost, D.J.; Katsura, T.</b> (2025). Bridgmanite’s ferric iron content determined Earth’s oxidation state. <i>Nature Geoscience 18(7)</i>: 670-674. <a href=\"https://dx.doi.org/10.1038/s41561-025-01725-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01725-0</a>","StandardTitle":"Bridgmanite’s ferric iron content determined Earth’s oxidation state","AuthorsString":"Wang, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":367805,"RR":"(2023). Bubble bursts increase melt rates of tidewater glaciers. <i>Nature Geoscience 16(10)</i>: 835-836. <a href=\"https://dx.doi.org/10.1038/s41561-023-01271-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01271-7</a>","StandardTitle":"Bubble bursts increase melt rates of tidewater glaciers","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":371747,"RR":"<b>Kendall, B.</b> (2023). Butterfly effect of shallow-ocean deoxygenation on past marine biodiversity. <i>Nature Geoscience 16(12)</i>: 1080-1081. <a href=\"https://dx.doi.org/10.1038/s41561-023-01310-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01310-3</a>","StandardTitle":"Butterfly effect of shallow-ocean deoxygenation on past marine biodiversity","AuthorsString":"Kendall, B.","BibLvlCode":"AS"},{"BRefID":338977,"RR":"<b>Sulpis, O.; Jeansson, E.; Dinauer, A.; Lauvset, S.K.; Middelburg, J.J.</b> (2021). Calcium carbonate dissolution patterns in the ocean. <i>Nature Geoscience 14(6)</i>: 423-428. <a href=\"https://dx.doi.org/10.1038/s41561-021-00743-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00743-y</a>","StandardTitle":"Calcium carbonate dissolution patterns in the ocean","AuthorsString":"Sulpis, O. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":334825,"RR":"<b>Howarth, J.D.; Orpin, A.R.; Kaneko, Y.; Strachan, L.J.; Nodder, S.D.; Mountjoy, J.J.; Barnes, P. M.; Bostock, H.C.; Holden, C.; Jones, K.; Çagatay, M.N.</b> (2021). Calibrating the marine turbidite palaeoseismometer using the 2016 Kaikōura earthquake. <i>Nature Geoscience 14(3)</i>: 161-167. <a href=\"https://dx.doi.org/10.1038/s41561-021-00692-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00692-6</a>","StandardTitle":"Calibrating the marine turbidite palaeoseismometer using the 2016 Kaikōura earthquake","AuthorsString":"Howarth, J.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":338972,"RR":"<b>Vanková, I.</b> (2021). Calving prediction from ice mélange motion. <i>Nature Geoscience 14(6)</i>: 357-358. <a href=\"https://dx.doi.org/10.1038/s41561-021-00752-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00752-x</a>","StandardTitle":"Calving prediction from ice mélange motion","AuthorsString":"Vanková, I.","BibLvlCode":"AS"},{"BRefID":391167,"RR":"<b>Bowen, J.C.; Wahyudio, P.J.; Anshari, G.Z.; Aluwihare, L.I.; Hoyt, A.M.</b> (2024). Canal networks regulate aquatic losses of carbon from degraded tropical peatlands. <i>Nature Geoscience 17(3)</i>: 213-218. <a href=\"https://dx.doi.org/10.1038/s41561-024-01383-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01383-8</a>","StandardTitle":"Canal networks regulate aquatic losses of carbon from degraded tropical peatlands","AuthorsString":"Bowen, J.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":356621,"RR":"<b>Pope, E.L.; Heijnen, M.S.; Talling, P.J.; Jacinto, R.S.; Gaillot, A.; Baker, M.L.; Hage, S.; Hasenhündl, M.; Heerema, C.J.; McGhee, C.; Ruffell, S.C.; Simmons, S.M.; Cartigny, M.J.B.; Clare, M.A.; Dennielou, B.; Parsons, D.R.; Peirce, C.; Urlaub, M.</b> (2022). Carbon and sediment fluxes inhibited in the submarine Congo Canyon by landslide-damming. <i>Nature Geoscience 15(10)</i>: 845-853. <a href=\"https://dx.doi.org/10.1038/s41561-022-01017-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01017-x</a>","StandardTitle":"Carbon and sediment fluxes inhibited in the submarine Congo Canyon by landslide-damming","AuthorsString":"Pope, E.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":344783,"RR":"<b>Aiuppa, A.; Casetta, F.; Coltorti, M.; Stagno, V.; Tamburello, G.</b> (2021). Carbon concentration increases with depth of melting in Earth’s upper mantle. <i>Nature Geoscience 14(9)</i>: 697-703. <a href=\"https://dx.doi.org/10.1038/s41561-021-00797-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00797-y</a>","StandardTitle":"Carbon concentration increases with depth of melting in Earth’s upper mantle","AuthorsString":"Aiuppa, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":221148,"RR":"<b>Bouillon, S.</b> (2011). Carbon cycle: storage beneath mangroves. <i>Nature Geoscience 4(5)</i>: 282-283. <a href=\"http://dx.doi.org/10.1038/ngeo1130\" target=\"_blank\">dx.doi.org/10.1038/ngeo1130</a>","StandardTitle":"Carbon cycle: storage beneath mangroves","AuthorsString":"Bouillon, S.","BibLvlCode":"AS"},{"BRefID":360449,"RR":"<b>Rogge, A.; Janout, M.; Loginova, N.; Trudnowska, E.; Hörstmann, C.; Wekerle, C.; Oziel, L.; Schourup-Kristensen, V.; Ruiz-Castillo, E.; Schulz, K.; Povazhnyy, V.V.; Iversen, M.H.; Waite, A.M.</b> (2023). Carbon dioxide sink in the Arctic Ocean from cross-shelf transport of dense Barents Sea water. <i>Nature Geoscience 16(1)</i>: 82-88. <a href=\"https://dx.doi.org/10.1038/s41561-022-01069-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01069-z</a>","StandardTitle":"Carbon dioxide sink in the Arctic Ocean from cross-shelf transport of dense Barents Sea water","AuthorsString":"Rogge, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":415781,"RR":"<b>Weiß, J.F.; Herzschuh, U.; Müller, J.; Liang, J.; Vorrath, M.-E.; Perfumo, A.; Stoof-Leichsenring, K.R.</b> (2025). Carbon drawdown by algal blooms during Antarctic Cold Reversal from sedimentary ancient DNA. <i>Nature Geoscience 18(9)</i>: 901–908. <a href=\"https://dx.doi.org/10.1038/s41561-025-01761-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01761-w</a>","StandardTitle":"Carbon drawdown by algal blooms during Antarctic Cold Reversal from sedimentary ancient DNA","AuthorsString":"Weiß, J.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392769,"RR":"<b>Filbee-Dexter, Karen; Pessarrodona, Albert; Pedersen, Morten F.; Wernberg, Thomas; Duarte, Carlos M.; Assis, Jorge; Bekkby, Trine; Burrows, Michael T.; Carlson, Daniel F.; Gattuso, Jean-Pierre; Gundersen, Hege; Hancke, Kasper; Krumhansl, Kira A.; Kuwae, Tomohiro; Middelburg, Jack J.; Moore, Pippa J.; Queirós, Ana M.; Smale, Dan A.; Sousa-Pinto, Isabel; Suzuki, Nobuhiro; Krause-Jensen, Dorte</b> (2024). Carbon export from seaweed forests to deep ocean sinks. <i>Nature Geoscience 17(6)</i>: 552-559. <a href=\"https://dx.doi.org/10.1038/s41561-024-01449-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01449-7</a>","StandardTitle":"Carbon export from seaweed forests to deep ocean sinks","AuthorsString":"Filbee-Dexter, Karen <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":347566,"RR":"<b>Ford, W.; Fox, J.</b> (2021). Carbon fate in lowland rivers. <i>Nature Geoscience 14(11)</i>: 802-803. <a href=\"https://dx.doi.org/10.1038/s41561-021-00849-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00849-3</a>","StandardTitle":"Carbon fate in lowland rivers","AuthorsString":"Ford, W.; Fox, J.","BibLvlCode":"AS"},{"BRefID":353954,"RR":"<b>Overholt, W.A.; Trumbore, S.; Xu, X.; Bornemann, T.L.V.; Probst, A.J.; Krüger Markus, M.; Herrmann, M.; Thamdrup, B.; Bristow, L.A.; Taubert, M.; Schwab, V.F.; Hölzer, M.; Marz, M.; Küsel, K.</b> (2022). Carbon fixation rates in groundwater similar to those in oligotrophic marine systems. <i>Nature Geoscience 15(7)</i>: 561-567. <a href=\"https://dx.doi.org/10.1038/s41561-022-00968-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00968-5</a>","StandardTitle":"Carbon fixation rates in groundwater similar to those in oligotrophic marine systems","AuthorsString":"Overholt, W.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":283777,"RR":"<b>Pabortsava, K.; Lampitt, R.S.; Benson, J.; Crowe, C.; McLachlan, R.; Le Moigne, F.A.C.; Moore, C.M.; Pebody, C.; Provost, P.; Rees, A.P.; Tilstone, G.H.; Woodward, M.S.</b> (2017). Carbon sequestration in the deep Atlantic enhanced by Saharan dust. <i>Nature Geoscience 10(3)</i>: 189-194. <a href=\"http://dx.doi.org/10.1038/ngeo2899\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2899</a>","StandardTitle":"Carbon sequestration in the deep Atlantic enhanced by Saharan dust","AuthorsString":"Pabortsava, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":415738,"RR":"<b>Peacock, C.L.</b> (2025). Carbon storage in coastal wetlands. <i>Nature Geoscience 18(9)</i>: 816–817. <a href=\"https://dx.doi.org/10.1038/s41561-025-01773-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01773-6</a>","StandardTitle":"Carbon storage in coastal wetlands","AuthorsString":"Peacock, C.L.","BibLvlCode":"AS"},{"BRefID":290722,"RR":"<b>Shields, M.R.; Bianchi, T.S.; Mohrig, D.; Hutchings, J.A.; Kenney, W.F.; Kolker, A.S.; Curtis, J.H.</b> (2017). Carbon storage in the Mississippi River delta enhanced by environmental engineering. <i>Nature Geoscience 10(11)</i>: 846-851. <a href=\"https://dx.doi.org/10.1038/ngeo3044\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3044</a>","StandardTitle":"Carbon storage in the Mississippi River delta enhanced by environmental engineering","AuthorsString":"Shields, M.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":360448,"RR":"<b>Manizza, M.</b> (2023). Carbon streams into the deep Arctic Ocean. <i>Nature Geoscience 16(1)</i>: 6-7. <a href=\"https://dx.doi.org/10.1038/s41561-022-01102-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01102-1</a>","StandardTitle":"Carbon streams into the deep Arctic Ocean","AuthorsString":"Manizza, M.","BibLvlCode":"AS"},{"BRefID":283773,"RR":"<b>Scher, H.D.</b> (2017). Carbon–ocean gateway links. <i>Nature Geoscience 10(3)</i>: 164-165. <a href=\"http://dx.doi.org/10.1038/ngeo2895\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2895</a>","StandardTitle":"Carbon–ocean gateway links","AuthorsString":"Scher, H.D.","BibLvlCode":"AS"},{"BRefID":243203,"RR":"<b>Salter, I.; Schiebel, R.; Ziveri, P.; Movellan, A.; Lampitt, R.; Wolff, G.A.</b> (2014). Carbonate counter pump stimulated by natural iron fertilization in the Polar Frontal Zone. <i>Nature Geoscience 7(12)</i>: 885–889. <a href=\"http://dx.doi.org/10.1038/ngeo2285\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2285</a>","StandardTitle":"Carbonate counter pump stimulated by natural iron fertilization in the Polar Frontal Zone","AuthorsString":"Salter, I. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":301865,"RR":"<b>Rennie, V.C.F.; Paris, G.; Sessions, A.L.; Abramovich, S.; Turchyn, A.V.; Adkins, J.F.</b> (2018). Cenozoic record of δ<sup>34</sup>S in foraminiferal calcite implies an early Eocene shift to deep-ocean sulfide burial. <i>Nature Geoscience 11(10)</i>: 761-765. <a href=\"https://dx.doi.org/10.1038/s41561-018-0200-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0200-y</a>","StandardTitle":"Cenozoic record of δ<sup>34</sup>S in foraminiferal calcite implies an early Eocene shift to deep-ocean sulfide burial","AuthorsString":"Rennie, V.C.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396661,"RR":"<b>Legrain, E.; Capron, E.; Menviel, L.; Wohleber, A.; Parrenin, F.; Teste, G.; Landais, A.; Bouchet, M.; Grilli, R.; Nehrbass-Ahles, C.; Moitinho-Silva, L.; Fischer, H.; Stocker, T.F.</b> (2024). Centennial-scale variations in the carbon cycle enhanced by high obliquity. <i>Nature Geoscience 17(11)</i>: 1154-1161. <a href=\"https://dx.doi.org/10.1038/s41561-024-01556-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01556-5</a>","StandardTitle":"Centennial-scale variations in the carbon cycle enhanced by high obliquity","AuthorsString":"Legrain, E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":371754,"RR":"<b>Ricour, F.; Guidi, L.; Gehlen, M.; DeVries, T.; Legendre, L.</b> (2023). Century-scale carbon sequestration flux throughout the ocean by the biological pump. <i>Nature Geoscience 16(12)</i>: 1105-1113. <a href=\"https://dx.doi.org/10.1038/s41561-023-01318-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01318-9</a>","StandardTitle":"Century-scale carbon sequestration flux throughout the ocean by the biological pump","AuthorsString":"Ricour, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":324984,"RR":"<b>Tamarin-Brodsky, T.; Hodges, K.; Hoskins , B.J.; Shepherd, T.G.</b> (2020). Changes in Northern Hemisphere temperature variability shaped by regional warming patterns. <i>Nature Geoscience 13(6)</i>: 414-421. <a href=\"https://dx.doi.org/10.1038/s41561-020-0576-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0576-3</a>","StandardTitle":"Changes in Northern Hemisphere temperature variability shaped by regional warming patterns","AuthorsString":"Tamarin-Brodsky, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":320516,"RR":"<b>Silvano, A.</b> (2020). Changes in the Southern Ocean. <i>Nature Geoscience 13(1)</i>: 4-5. <a href=\"https://dx.doi.org/10.1038/s41561-019-0516-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0516-2</a>","StandardTitle":"Changes in the Southern Ocean","AuthorsString":"Silvano, A.","BibLvlCode":"AS"},{"BRefID":281763,"RR":"<b>Tynan, E.</b> (2016). Changing icescapes. <i>Nature Geoscience 9(12)</i>: 869-869. <a href=\"http://dx.doi.org/10.1038/ngeo2853\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2853</a>","StandardTitle":"Changing icescapes","AuthorsString":"Tynan, E.","BibLvlCode":"AS"},{"BRefID":359503,"RR":"<b>Okuwaki, R.</b> (2022). Chasing supershear earthquakes. <i>Nature Geoscience 15(11)</i>: 863-864. <a href=\"https://dx.doi.org/10.1038/s41561-022-01054-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01054-6</a>","StandardTitle":"Chasing supershear earthquakes","AuthorsString":"Okuwaki, R.","BibLvlCode":"AS"},{"BRefID":234955,"RR":"<b>Li, M.; McNamara, A.K.; Garnero, E.J.</b> (2014). Chemical complexity of hotspots caused by cycling oceanic crust through mantle reservoirs. <i>Nature Geoscience 7(2120)</i>: 5 pp. <a href=\"http://dx.doi.org/10.1038/ngeo2120\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2120</a>","StandardTitle":"Chemical complexity of hotspots caused by cycling oceanic crust through mantle reservoirs","AuthorsString":"Li, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":324987,"RR":"<b>Su, J.; Cai, W.-J.; Brodeur, J.; Chen, B.; Hussain, N.; Yao, Y.; Ni, C.; Testa, J.M.; Li, M.; Xie, X.; Ni, W.; Scaboo, K.M.; Xu, Y.-Y.; Cornwell, J.; Gurbisz, C.; Owens, M.S.; Waldbusser, G.G.; Dai, M.; Kemp, W.M.</b> (2020). Chesapeake Bay acidification buffered by spatially decoupled carbonate mineral cycling. <i>Nature Geoscience 13(6)</i>: 441-447. <a href=\"https://dx.doi.org/10.1038/s41561-020-0584-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0584-3</a>","StandardTitle":"Chesapeake Bay acidification buffered by spatially decoupled carbonate mineral cycling","AuthorsString":"Su, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":368758,"RR":"<b>Senel, C.B.; Kaskes, P.; Temel, O.; Vellekoop, J.; Goderis, S.; DePalma, R.; Prins, M.A.; Claeys, P.; Karatekin, Ö.</b> (2023). Chicxulub impact winter sustained by fine silicate dust. <i>Nature Geoscience 16(11)</i>: 1033-1040. <a href=\"https://dx.doi.org/10.1038/s41561-023-01290-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01290-4</a>","StandardTitle":"Chicxulub impact winter sustained by fine silicate dust","AuthorsString":"Senel, C.B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":404826,"RR":"(2024). Choppy seas for deep ocean drilling. <i>Nature Geoscience 17(12)</i>: 1183-1183. <a href=\"https://dx.doi.org/10.1038/s41561-024-01616-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01616-w</a>","StandardTitle":"Choppy seas for deep ocean drilling","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":211515,"RR":"<b>Gibson, S.A.</b> (2011). Christmas recycling. <i>Nature Geoscience 4(12)</i>: 823-824. <a href=\"http://dx.doi.org/10.1038/ngeo1337\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1337</a>","StandardTitle":"Christmas recycling","AuthorsString":"Gibson, S.A.","BibLvlCode":"AS"},{"BRefID":404834,"RR":"(2024). Chronic intense bottom trawling reduces marine carbon sequestration. <i>Nature Geoscience 17(12)</i>: 1200-1201. <a href=\"https://dx.doi.org/10.1038/s41561-024-01589-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01589-w</a>","StandardTitle":"Chronic intense bottom trawling reduces marine carbon sequestration","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":341621,"RR":"<b>Brown, P.J.; McDonagh, E.L.; Sanders, R.; Watson, A.J.; Wanninkhof, R.; King, B.A.; Smeed, D.A.; Baringer, M.O.; Meinen, C.S.; Schuster, U.; Yool, A.; Messias, M.-J.</b> (2021). Circulation-driven variability of Atlantic anthropogenic carbon transports and uptake. <i>Nature Geoscience 14(8)</i>: 571-577. <a href=\"https://dx.doi.org/10.1038/s41561-021-00774-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00774-5</a>","StandardTitle":"Circulation-driven variability of Atlantic anthropogenic carbon transports and uptake","AuthorsString":"Brown, P.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":436559,"RR":"<b>Baker, D.M.; Wang, M.</b> (2025). Climate change fuels the Great Atlantic <i>Sargassum</i> Belt. <i>Nature Geoscience 18(12)</i>: 1185-1186. <a href=\"https://dx.doi.org/10.1038/s41561-025-01871-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01871-5</a>","StandardTitle":"Climate change fuels the Great Atlantic <i>Sargassum</i> Belt","AuthorsString":"Baker, D.M.; Wang, M.","BibLvlCode":"AS"},{"BRefID":286593,"RR":"<b>Pancost, R.D.</b> (2017). Climate change narratives. <i>Nature Geoscience 10(7)</i>: 466-468. <a href=\"https://dx.doi.org/10.1038/ngeo2981\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2981</a>","StandardTitle":"Climate change narratives","AuthorsString":"Pancost, R.D.","BibLvlCode":"AS"},{"BRefID":310829,"RR":"<b>Lantink, M.L.; Davies, J.H.F.L.; Mason, P.R.D.; Schaltegger, U.; Hilgen, F.J.</b> (2019). Climate control on banded iron formations linked to orbital eccentricity. <i>Nature Geoscience 12(5)</i>: 369-374. <a href=\"https://dx.doi.org/10.1038/s41561-019-0332-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0332-8</a>","StandardTitle":"Climate control on banded iron formations linked to orbital eccentricity","AuthorsString":"Lantink, M.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":337162,"RR":"<b>Piecuch, C.G.; Kemp, A.C.; Gebbie, G.; Meltzner, A.J.</b> (2021). Climate did not drive Common Era Maldivian sea-level lowstands. <i>Nature Geoscience 14(5)</i>: 273-275. <a href=\"https://hdl.handle.net/10.1038/s41561-021-00731-2\" target=\"_blank\">https://hdl.handle.net/10.1038/s41561-021-00731-2</a>","StandardTitle":"Climate did not drive Common Era Maldivian sea-level lowstands","AuthorsString":"Piecuch, C.G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":438184,"RR":"<b>Boucharel, J.; Almar, R.; Jin, F.-F.; Zhao, S.; Stuecker, M.F.; Dewitte, B.</b> (2026). Climate mode interactions amplify coastal flood risks and their seasonal predictability. <i>Nature Geoscience 19(3)</i>: 317-324. <a href=\"https://dx.doi.org/10.1038/s41561-025-01903-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01903-0</a>","StandardTitle":"Climate mode interactions amplify coastal flood risks and their seasonal predictability","AuthorsString":"Boucharel, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":408335,"RR":"<b>Fakhraee, M.; Bauer, K.W.; Planavsky, N.J.; Reinhard, C.T.; Crowe, S.A.</b> (2025). Climate stabilization by alkalinity production from pyrite burial during oceanic anoxia. <i>Nature Geoscience 18(6)</i>: 495-502. <a href=\"https://dx.doi.org/10.1038/s41561-025-01698-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01698-0</a>","StandardTitle":"Climate stabilization by alkalinity production from pyrite burial during oceanic anoxia","AuthorsString":"Fakhraee, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":303660,"RR":"<b>Cui, Y.</b> (2018). Climate swings in extinction. <i>Nature Geoscience 11(12)</i>: 889-890. <a href=\"https://dx.doi.org/10.1038/s41561-018-0264-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0264-8</a>","StandardTitle":"Climate swings in extinction","AuthorsString":"Cui, Y.","BibLvlCode":"AS"},{"BRefID":371752,"RR":"<b>King, M.A.; Lyu, K.; Zhang, X.</b> (2023). Climate variability a key driver of recent Antarctic ice-mass change. <i>Nature Geoscience 16(12)</i>: 1128-1135. <a href=\"https://dx.doi.org/10.1038/s41561-023-01317-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01317-w</a>","StandardTitle":"Climate variability a key driver of recent Antarctic ice-mass change","AuthorsString":"King, M.A.; Lyu, K.; Zhang, X.","BibLvlCode":"AS"},{"BRefID":359513,"RR":"<b>Chen, Y.; Kirwan, M.L.</b> (2022). Climate-driven decoupling of wetland and upland biomass trends on the mid-Atlantic coast. <i>Nature Geoscience 15(11)</i>: 913-918. <a href=\"https://dx.doi.org/10.1038/s41561-022-01041-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01041-x</a>","StandardTitle":"Climate-driven decoupling of wetland and upland biomass trends on the mid-Atlantic coast","AuthorsString":"Chen, Y.; Kirwan, M.L.","BibLvlCode":"AS"},{"BRefID":320549,"RR":"<b>Kench, P.S.; McLean, R.F.; Owen, S.D.; Ryan, E.; Morgan, K.M.; Ke, L.; Wang, X.; Roy, K.</b> (2020). Climate-forced sea-level lowstands in the Indian Ocean during the last two millennia. <i>Nature Geoscience 13(1)</i>: 61-64. <a href=\"https://dx.doi.org/10.1038/s41561-019-0503-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0503-7</a>","StandardTitle":"Climate-forced sea-level lowstands in the Indian Ocean during the last two millennia","AuthorsString":"Kench, P.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":356611,"RR":"<b>Duncan, B.; McKay, R.; Levy, R.; Naish, T.; Prebble, J.G.; Sangiorgi, F.; Krishnan, S.; Hoem, F.; Clowes, C.; Dunkley Jones, T.; Gasson, E.; Kraus, C.; Kulhanek, D.K.; Meyers, S.R.; Moossen, H.; Warren, C.; Willmott, V.; Ventura, G.T.; Bendle, J.</b> (2022). Climatic and tectonic drivers of late Oligocene Antarctic ice volume. <i>Nature Geoscience 15(10)</i>: 819-825. <a href=\"https://dx.doi.org/10.1038/s41561-022-01025-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01025-x</a>","StandardTitle":"Climatic and tectonic drivers of late Oligocene Antarctic ice volume","AuthorsString":"Duncan, B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":303725,"RR":"<b>Alfaro-Sánchez, R.; Nguyen, H.; Klesse, S.; Hudson, A.; Belmecheri, S.; Köse, N.; Diaz, H.F.; Monson, R.K.; Villaba, R.; Trouet, V.</b> (2018). Climatic and volcanic forcing of tropical belt northern boundary over the past 800 years. <i>Nature Geoscience 11(12)</i>: 933-938. <a href=\"https://dx.doi.org/10.1038/s41561-018-0242-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0242-1</a>","StandardTitle":"Climatic and volcanic forcing of tropical belt northern boundary over the past 800 years","AuthorsString":"Alfaro-Sánchez, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":353948,"RR":"(2022). Closed ocean gateways in the Canadian archipelago are key to glaciation in Scandinavia. <i>Nature Geoscience 15(6)</i>: 436-437. <a href=\"https://dx.doi.org/10.1038/s41561-022-00959-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00959-6</a>","StandardTitle":"Closed ocean gateways in the Canadian archipelago are key to glaciation in Scandinavia","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":281761,"RR":"<b>Mauritsen, T.</b> (2016). Clouds cooled the Earth. <i>Nature Geoscience 9(12)</i>: 865-867. <a href=\"http://dx.doi.org/10.1038/ngeo2838\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2838</a>","StandardTitle":"Clouds cooled the Earth","AuthorsString":"Mauritsen, T.","BibLvlCode":"AS"},{"BRefID":336525,"RR":"<b>Bufe, A.; Hovius, N.; Emberson, R.; Rugenstein, J.K.C.; Galy, A.; Hassenruck-Gudipati, H.J.; Chang, J.-M.</b> (2021). Co-variation of silicate, carbonate and sulfide weathering drives CO<sub>2</sub> release with erosion. <i>Nature Geoscience 14(4)</i>: 211-216. <a href=\"https://dx.doi.org/10.1038/s41561-021-00714-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00714-3</a>","StandardTitle":"Co-variation of silicate, carbonate and sulfide weathering drives CO<sub>2</sub> release with erosion","AuthorsString":"Bufe, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":415762,"RR":"<b>Hall, N.; Wong, W.W.; Lappan, R.; Ricci, F.; Jeppe, K.J.; Glud, R.N.; Kawaichi, S.; Rotaru, A-E.; Greening, C.; Cook, P.L.M.</b> (2025). Coastal methane emissions driven by aerotolerant methanogens using seaweed and seagrass metabolites. <i>Nature Geoscience 18(9)</i>: 854–861. <a href=\"https://dx.doi.org/10.1038/s41561-025-01768-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01768-3</a>","StandardTitle":"Coastal methane emissions driven by aerotolerant methanogens using seaweed and seagrass metabolites","AuthorsString":"Hall, N. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":250194,"RR":"<b>Barnard, P.L.; Short, A.D.; Harley, M.D.; Splinter, K.D.; Vitousek, S.; Turner, I.L.; Allan, J.; Banno, M.; Bryan, K.R.; Doria, A.; Hansen, J.E.; Kato, S.; Kuriyama, Y.; Randall-Goodwin, E.; Ruggiero, P.; Walker, I.J.; Heathfield, D.K.</b> (2015). Coastal vulnerability across the Pacific dominated by El Niño/Southern Oscillation. <i>Nature Geoscience 8(10)</i>: 801–807. <a href=\"http://dx.doi.org/10.1038/ngeo2539\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2539</a>","StandardTitle":"Coastal vulnerability across the Pacific dominated by El Niño/Southern Oscillation","AuthorsString":"Barnard, P.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":371751,"RR":"<b>Koffman, B.G.; Osman, M.B.; Criscitiello, A.S.; Guest, S.</b> (2023). Collaboration between women helps close the gender gap in ice core science. <i>Nature Geoscience 16(12)</i>: 1088-1091. <a href=\"https://dx.doi.org/10.1038/s41561-023-01315-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01315-y</a>","StandardTitle":"Collaboration between women helps close the gender gap in ice core science","AuthorsString":"Koffman, B.G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":313843,"RR":"<b>Rodrigues, R.R.; Taschetto, A.S.; Sen Gupta, A.; Foltz, G.R.</b> (2019). Common cause for severe droughts in South America and marine heatwaves in the South Atlantic. <i>Nature Geoscience 12(8)</i>: 620-626. <a href=\"https://dx.doi.org/10.1038/s41561-019-0393-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0393-8</a>","StandardTitle":"Common cause for severe droughts in South America and marine heatwaves in the South Atlantic","AuthorsString":"Rodrigues, R.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":282625,"RR":"<b>Riebesell, U.; Bach, L.T.; Bellerby, R.G.J.; Monsalve, J.R.B.; Boxhammer, T.; Czerny, J.; Larsen, A.; Ludwig, A.; Schulz, K.G.</b> (2017). Competitive fitness of a predominant pelagic calcifier impaired by ocean acidification. <i>Nature Geoscience 10(1)</i>: 19-23. <a href=\"http://dx.doi.org/10.1038/ngeo2854\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2854</a>","StandardTitle":"Competitive fitness of a predominant pelagic calcifier impaired by ocean acidification","AuthorsString":"Riebesell, U. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":321493,"RR":"<b>Bamber, J.L.; Dawson, G.J.</b> (2020). Complex evolving patterns of mass loss from Antarctica’s largest glacier. <i>Nature Geoscience 13(2)</i>: 127-131. <a href=\"https://dx.doi.org/10.1038/s41561-019-0527-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0527-z</a>","StandardTitle":"Complex evolving patterns of mass loss from Antarctica’s largest glacier","AuthorsString":"Bamber, J.L.; Dawson, G.J.","BibLvlCode":"AS"},{"BRefID":349084,"RR":"(2022). Complexities of coastal resilience. <i>Nature Geoscience 15(1)</i>: 1-1. <a href=\"https://dx.doi.org/10.1038/s41561-021-00884-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00884-0</a>","StandardTitle":"Complexities of coastal resilience","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":355462,"RR":"<b>Spencer, C.J.; Davies, N.S.; Gernon, T.M.; Wang, X.; McMahon, W.J.; Morrell, T.R.I.; Hincks, T.; Pufahl, P.K.; Brasier, A.; Seraine, M.; Lu, G.-M.</b> (2022). Composition of continental crust altered by the emergence of land plants. <i>Nature Geoscience 15(9)</i>: 735-740. <a href=\"https://dx.doi.org/10.1038/s41561-022-00995-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00995-2</a>","StandardTitle":"Composition of continental crust altered by the emergence of land plants","AuthorsString":"Spencer, C.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":302860,"RR":"<b>Markle, B.R.; Steig, E.J.; Roe, G.H.; Winckler, G.; McConnell, J.R.</b> (2018). Concomitant variability in high-latitude aerosols, water isotopes and the hydrologic cycle. <i>Nature Geoscience 11(11)</i>: 853-859. <a href=\"https://dx.doi.org/10.1038/s41561-018-0210-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0210-9</a>","StandardTitle":"Concomitant variability in high-latitude aerosols, water isotopes and the hydrologic cycle","AuthorsString":"Markle, B.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":290665,"RR":"(2017). Connect the drops. <i>Nature Geoscience 10(11)</i>: 799-799. <a href=\"https://dx.doi.org/10.1038/ngeo3058\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3058</a>","StandardTitle":"Connect the drops","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":318162,"RR":"<b>Kölling, M.; Bouimetarhan, I.; Bowles, M.W.; Felis, T.; Goldhammer, T.; Hinrichs, K.U.; Schulz, M.; Zabel, M.</b> (2019). Consistent CO<sub>2</sub> release by pyrite oxidation on continental shelves prior to glacial terminations. <i>Nature Geoscience 12(11)</i>: 929-934. <a href=\"https://dx.doi.org/10.1038/s41561-019-0465-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0465-9</a>","StandardTitle":"Consistent CO<sub>2</sub> release by pyrite oxidation on continental shelves prior to glacial terminations","AuthorsString":"Kölling, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":313846,"RR":"<b>The PAGES 2k Consortium</b> (2019). Consistent multidecadal variability in global temperature reconstructions and simulations over the Common Era. <i>Nature Geoscience 12(8)</i>: 643-649. <a href=\"https://dx.doi.org/10.1038/s41561-019-0400-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0400-0</a>","StandardTitle":"Consistent multidecadal variability in global temperature reconstructions and simulations over the Common Era","AuthorsString":"The PAGES 2k Consortium","BibLvlCode":"AS"},{"BRefID":419030,"RR":"<b>He, Y.; Kadko, D.C.; Stephens, M.P.; Sheridan, M.T.; Buck, C.S.; Marsay, C.M.; Landing, W.M.; Zheng, M.; Liu, P.</b> (2025). Constraining aerosol deposition over the global ocean. <i>Nature Geoscience 18(10)</i>: 966-974. <a href=\"https://dx.doi.org/10.1038/s41561-025-01785-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01785-2</a>","StandardTitle":"Constraining aerosol deposition over the global ocean","AuthorsString":"He, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":298375,"RR":"<b>Lenton, A.</b> (2018). Constraining ocean transport. <i>Nature Geoscience 11(7)</i>: 461-462. <a href=\"https://dx.doi.org/10.1038/s41561-018-0165-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0165-x</a>","StandardTitle":"Constraining ocean transport","AuthorsString":"Lenton, A.","BibLvlCode":"AS"},{"BRefID":345744,"RR":"<b>Johnson, K.S.; Bif, M.B.</b> (2021). Constraint on net primary productivity of the global ocean by Argo oxygen measurements. <i>Nature Geoscience 14(10)</i>: 769-774. <a href=\"https://dx.doi.org/10.1038/s41561-021-00807-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00807-z</a>","StandardTitle":"Constraint on net primary productivity of the global ocean by Argo oxygen measurements","AuthorsString":"Johnson, K.S.; Bif, M.B.","BibLvlCode":"AS"},{"BRefID":282629,"RR":"<b>Blättler, C.L.; Kump, L.R.; Fischer, W.W.; Paris, G.; Kasbohm, J.J.; Higgins, J.A.</b> (2017). Constraints on ocean carbonate chemistry and pCO<sub>2</sub> in the Archaean and Palaeoproterozoic. <i>Nature Geoscience 10(1)</i>: 41-45. <a href=\"http://dx.doi.org/10.1038/ngeo2844\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2844</a>","StandardTitle":"Constraints on ocean carbonate chemistry and pCO<sub>2</sub> in the Archaean and Palaeoproterozoic","AuthorsString":"Blättler, C.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":245789,"RR":"<b>Gazel, E.; Hayes, J.L.; Hoernle, K.; Kelemen, P.; Everson, E.; Holbrook, W.S.; Hauff, F.; van den Bogaard, P.; Vance, E.A.; Chu, S.; Calvert, A.J.; Carr, A.J.; Yogodzinski, G.M.</b> (2015). Continental crust generated in oceanic arcs. <i>Nature Geoscience 8(4)</i>: 321–327. <a href=\"http://dx.doi.org/10.1038/ngeo2392\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2392</a>","StandardTitle":"Continental crust generated in oceanic arcs","AuthorsString":"Gazel, E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":439208,"RR":"<b>Gómez-Frutos, D.; Castro, A.; Balázs, A.; Gerya, T.</b> (2026). Continental evolution influenced by relamination of deeply subducted continental crust. <i>Nature Geoscience 19(5)</i>: 589-595. <a href=\"https://dx.doi.org/10.1038/s41561-026-01963-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01963-w</a>","StandardTitle":"Continental evolution influenced by relamination of deeply subducted continental crust","AuthorsString":"Gómez-Frutos, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":341641,"RR":"<b>Madella, A.; Ehlers, T.A.</b> (2021). Contribution of background seismicity to forearc uplift. <i>Nature Geoscience 14(8)</i>: 620-625. <a href=\"https://dx.doi.org/10.1038/s41561-021-00779-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00779-0</a>","StandardTitle":"Contribution of background seismicity to forearc uplift","AuthorsString":"Madella, A.; Ehlers, T.A.","BibLvlCode":"AS"},{"BRefID":296436,"RR":"<b>Elbert, W.; Weber, B.; Burrows, S.M.; Steinkamp, J.; Büdel, B.; Andreae, M.O.; Pöschl, U.</b> (2012). Contribution of cryptogamic covers to the global cycles of carbon and nitrogen. <i>Nature Geoscience 5(7)</i>: 459-462. <a href=\"https://dx.doi.org/10.1038/ngeo1486\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo1486</a>","StandardTitle":"Contribution of cryptogamic covers to the global cycles of carbon and nitrogen","AuthorsString":"Elbert, W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":405771,"RR":"<b>Aparicio, M.; Le Bihan, A.; Jeandel, C.; Fabre, S.; Almar, R.; Mingo, I.M.</b> (2025). Contribution of sandy beaches to the global marine silicon cycle. <i>Nature Geoscience 18(2)</i>: 154-159. <a href=\"https://dx.doi.org/10.1038/s41561-024-01628-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01628-6</a>","StandardTitle":"Contribution of sandy beaches to the global marine silicon cycle","AuthorsString":"Aparicio, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":233941,"RR":"<b>Quinn, P.K.; Bates, T.S.; Schulz, K.S.; Coffman, D.J.; Frossard, A.A.; Russell, L.M.; Keene, W.C.; Kieber, D.J.</b> (2014). Contribution of sea surface carbon pool to organic matter enrichment in sea spray aerosol. <i>Nature Geoscience 7(3)</i>: 228-232. <a href=\"http://dx.doi.org/10.1038/ngeo2092\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2092</a>","StandardTitle":"Contribution of sea surface carbon pool to organic matter enrichment in sea spray aerosol","AuthorsString":"Quinn, P.K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":290681,"RR":"<b>Ruan, X.; Thompson, A.F.; Flexas, M.M.; Sprintall, J.</b> (2017). Contribution of topographically generated submesoscale turbulence to Southern Ocean overturning. <i>Nature Geoscience 10(11)</i>: 840-845. <a href=\"https://dx.doi.org/10.1038/ngeo3053\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3053</a>","StandardTitle":"Contribution of topographically generated submesoscale turbulence to Southern Ocean overturning","AuthorsString":"Ruan, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":371761,"RR":"<b>Fan, S.; Prior, D.J.</b> (2023). Cool ice with hot properties. <i>Nature Geoscience 16(12)</i>: 1073-1073. <a href=\"https://dx.doi.org/10.1038/s41561-023-01330-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01330-z</a>","StandardTitle":"Cool ice with hot properties","AuthorsString":"Fan, S.; Prior, D.J.","BibLvlCode":"AS"},{"BRefID":405769,"RR":"<b>Mason, R.A.B.; Bozec, Y.-M.; Mumby, P.J.</b> (2025). Coral bleaching and mortality overestimated in projections based on Degree Heating Months. <i>Nature Geoscience 18(2)</i>: 120-123. <a href=\"https://dx.doi.org/10.1038/s41561-024-01635-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01635-7</a>","StandardTitle":"Coral bleaching and mortality overestimated in projections based on Degree Heating Months","AuthorsString":"Mason, R.A.B.; Bozec, Y.-M.; Mumby, P.J.","BibLvlCode":"AS"},{"BRefID":337181,"RR":"<b>Guo, H.; McGuire, J.J.; Zhang, H.</b> (2021). Correlation of porosity variations and rheological transitions on the southern Cascadia megathrust. <i>Nature Geoscience 14(5)</i>: 341-348. <a href=\"https://hdl.handle.net/10.1038/s41561-021-00740-1\" target=\"_blank\">https://hdl.handle.net/10.1038/s41561-021-00740-1</a>","StandardTitle":"Correlation of porosity variations and rheological transitions on the southern Cascadia megathrust","AuthorsString":"Guo, H.; McGuire, J.J.; Zhang, H.","BibLvlCode":"AS"},{"BRefID":261253,"RR":"<b>Duprat, L.P.A.M.; Bigg, G.R.; Wilton, D.J.</b> (2016). Corrigendum: Enhanced Southern Ocean marine productivity due to fertilization by giant icebergs. <i>Nature Geoscience 9(9)</i>: 728-728. <a href=\"http://dx.doi.org/10.1038/ngeo2809\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2809</a>","StandardTitle":"Corrigendum: Enhanced Southern Ocean marine productivity due to fertilization by giant icebergs","AuthorsString":"Duprat, L.P.A.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":247387,"RR":"<b>Schaller, M.F.</b> (2015). Corrosive circulation. <i>Nature Geoscience 8(6)</i>: 429 - 430. <a href=\"http://dx.doi.org/10.1038/ngeo2446\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2446</a>","StandardTitle":"Corrosive circulation","AuthorsString":"Schaller, M.F.","BibLvlCode":"AS"},{"BRefID":404841,"RR":"<b>Li, M.; Kump, L.R.; Ridgwell, A.; Tierney, J.E.; Hakim, G.J.; Malevich, S.B.; Poulsen, C.J.; Tardif, R.; Zhang, H.; Zhu, J.</b> (2024). Coupled decline in ocean pH and carbonate saturation during the Palaeocene–Eocene Thermal Maximum. <i>Nature Geoscience 17(12)</i>: 1299-1305. <a href=\"https://dx.doi.org/10.1038/s41561-024-01579-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01579-y</a>","StandardTitle":"Coupled decline in ocean pH and carbonate saturation during the Palaeocene–Eocene Thermal Maximum","AuthorsString":"Li, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":329219,"RR":"<b>Leutert, T.J.; Auderset, A.; Martínez-Garcia, A.; Modestou, S.; Meckler, A.N.</b> (2020). Coupled Southern Ocean cooling and Antarctic ice sheet expansion during the middle Miocene. <i>Nature Geoscience 13(9)</i>: 634-639. <a href=\"https://dx.doi.org/10.1038/s41561-020-0623-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0623-0</a>","StandardTitle":"Coupled Southern Ocean cooling and Antarctic ice sheet expansion during the middle Miocene","AuthorsString":"Leutert, T.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":363317,"RR":"<b>Lawrence, J.D.; Washam, P.M.; Stevens, C.; Hulbe, C.; Horgan, H.J.; Dunbar, G.; Calkin, T.; Stewart, C.; Robinson, N.; Mullen, A.D.; Meister, M.R.; Hurwitz, B.C.; Quartini, E.; Dichek, D.J.G.; Spears, A.; Schmidt, B.E.</b> (2023). Crevasse refreezing and signatures of retreat observed at Kamb Ice Stream grounding zone. <i>Nature Geoscience 16(3)</i>: 238-243. <a href=\"https://dx.doi.org/10.1038/s41561-023-01129-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01129-y</a>","StandardTitle":"Crevasse refreezing and signatures of retreat observed at Kamb Ice Stream grounding zone","AuthorsString":"Lawrence, J.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":324016,"RR":"<b>Collins, W.J.; Murphy, J.B.; Johnson, T.E.; Huang, H.-Q.</b> (2020). Critical role of water in the formation of continental crust. <i>Nature Geoscience 13(5)</i>: 331-338. <a href=\"https://dx.doi.org/10.1038/s41561-020-0573-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0573-6</a>","StandardTitle":"Critical role of water in the formation of continental crust","AuthorsString":"Collins, W.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392767,"RR":"<b>Grandjean, T.J.; Weenink, R.; van der Wal, D.; Addink, E.A.; Hu, Z.; Liu, S.; Wang, Z.B.; Yuan, L.; Bouma, T.</b> (2024). Critical turbidity thresholds for maintenance of estuarine tidal flats worldwide. <i>Nature Geoscience 17(6)</i>: 539-544. <a href=\"https://dx.doi.org/10.1038/s41561-024-01431-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01431-3</a>","StandardTitle":"Critical turbidity thresholds for maintenance of estuarine tidal flats worldwide","AuthorsString":"Grandjean, T.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":249208,"RR":"<b>Meredith, E.P.; Semenov, V.A.; Maraun, D.; Park, W.; Chernokulsky, A.V.</b> (2015). Crucial role of Black Sea warming in amplifying the 2012 Krymsk precipitation extreme. <i>Nature Geoscience 8(8)</i>: 615-619. <a href=\"http://dx.doi.org/10.1038/ngeo2483\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2483</a>","StandardTitle":"Crucial role of Black Sea warming in amplifying the 2012 Krymsk precipitation extreme","AuthorsString":"Meredith, E.P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392284,"RR":"<b>Alcott, L.J.; Walton, C.; Planavsky, N.J.; Shorttle, O.; Mills, B.J.W.</b> (2024). Crustal carbonate build-up as a driver for Earth’s oxygenation. <i>Nature Geoscience 17(5)</i>: 458-464. <a href=\"https://dx.doi.org/10.1038/s41561-024-01417-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01417-1</a>","StandardTitle":"Crustal carbonate build-up as a driver for Earth’s oxygenation","AuthorsString":"Alcott, L.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396662,"RR":"<b>Black, B.A.; Karlstrom, L.; Mills, B.J.W.; Mather, T.A.; Rudolph, M.L.; Longman, J.; Merdith, A.</b> (2024). Cryptic degassing and protracted greenhouse climates after flood basalt events. <i>Nature Geoscience 17(11)</i>: 1162-1168. <a href=\"https://dx.doi.org/10.1038/s41561-024-01574-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01574-3</a>","StandardTitle":"Cryptic degassing and protracted greenhouse climates after flood basalt events","AuthorsString":"Black, B.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":286598,"RR":"<b>Jenner, F.E.</b> (2017). Cumulate causes for the low contents of sulfide-loving elements in the continental crust. <i>Nature Geoscience 10(7)</i>: 524-529. <a href=\"https://dx.doi.org/10.1038/ngeo2965\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2965</a>","StandardTitle":"Cumulate causes for the low contents of sulfide-loving elements in the continental crust","AuthorsString":"Jenner, F.E.","BibLvlCode":"AS"},{"BRefID":334306,"RR":"<b>Caesar, L.; McCarthy, G.D.; Thornalley, D.J.R.; Cahill, N.; Rahmstorf, S.</b> (2021). Current Atlantic Meridional Overturning Circulation weakest in last millennium. <i>Nature Geoscience 14(3)</i>: 118-120. <a href=\"https://dx.doi.org/10.1038/s41561-021-00699-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00699-z</a>","StandardTitle":"Current Atlantic Meridional Overturning Circulation weakest in last millennium","AuthorsString":"Caesar, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359505,"RR":"<b>Hermann, J.</b> (2022). Cycles of serpentines. <i>Nature Geoscience 15(11)</i>: 865-865. <a href=\"https://dx.doi.org/10.1038/s41561-022-01063-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01063-5</a>","StandardTitle":"Cycles of serpentines","AuthorsString":"Hermann, J.","BibLvlCode":"AS"},{"BRefID":356591,"RR":"<b>Sheward, R.M.</b> (2022). Cycling carbon with coccolithophores. <i>Nature Geoscience 15(10)</i>: 758-759. <a href=\"https://dx.doi.org/10.1038/s41561-022-01039-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01039-5</a>","StandardTitle":"Cycling carbon with coccolithophores","AuthorsString":"Sheward, R.M.","BibLvlCode":"AS"},{"BRefID":363735,"RR":"<b>Martin-Puertas, C.; Hernandez, A.; Pardo-Igúzquiza, E.; Boyall, L.A.; Brierley, C.; Jiang, Z.; Tjallingii, R.; Blockley, S.P.E.; Rodríguez-Tovar, F.J.</b> (2023). Dampened predictable decadal North Atlantic climate fluctuations due to ice melting. <i>Nature Geoscience 16(4)</i>: 357-362. <a href=\"https://dx.doi.org/10.1038/s41561-023-01145-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01145-y</a>","StandardTitle":"Dampened predictable decadal North Atlantic climate fluctuations due to ice melting","AuthorsString":"Martin-Puertas, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":313842,"RR":"<b>Simpson, I.R.; Yeager, S.G.; McKinnon, K.A.; Deser, C.</b> (2019). Decadal predictability of late winter precipitation in western Europe through an ocean–jet stream connection. <i>Nature Geoscience 12(8)</i>: 613-619. <a href=\"https://dx.doi.org/10.1038/s41561-019-0391-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0391-x</a>","StandardTitle":"Decadal predictability of late winter precipitation in western Europe through an ocean–jet stream connection","AuthorsString":"Simpson, I.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":320543,"RR":"<b>Osborne, E.B.; Thunell, R.C.; Gruber, N.; Feely, R.A.; Benitez-Nelson, C.R.</b> (2020). Decadal variability in twentieth-century ocean acidification in the California Current Ecosystem. <i>Nature Geoscience 13(1)</i>: 43-49. <a href=\"https://dx.doi.org/10.1038/s41561-019-0499-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0499-z</a>","StandardTitle":"Decadal variability in twentieth-century ocean acidification in the California Current Ecosystem","AuthorsString":"Osborne, E.B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":363318,"RR":"<b>Batchelor, C.J.; Marcott, S.A.; Orland, I.J.; HE, F.; Edwards, R.L.</b> (2023). Decadal warming events extended into central North America during the last glacial period. <i>Nature Geoscience 16(3)</i>: 257-261. <a href=\"https://dx.doi.org/10.1038/s41561-023-01132-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01132-3</a>","StandardTitle":"Decadal warming events extended into central North America during the last glacial period","AuthorsString":"Batchelor, C.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":290675,"RR":"<b>Wurtsbaugh, W.A.; Miller, C.; Null, S.E.; DeRose, R.J.; Wilcock, P.; Hahnenberger, M.; Howe, F.; Moore, J.</b> (2017). Decline of the world's saline lakes. <i>Nature Geoscience 10(11)</i>: 816-821. <a href=\"https://dx.doi.org/10.1038/ngeo3052\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3052</a>","StandardTitle":"Decline of the world's saline lakes","AuthorsString":"Wurtsbaugh, W.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359486,"RR":"<b>Zhang, Q.; Bendif, E.M.; Zhou, Y.; Nevado, B.; Shafiee, R.; Rickaby, R.E.M.</b> (2022). Declining metal availability in the Mesozoic seawater reflected in phytoplankton succession. <i>Nature Geoscience 15(11)</i>: 932-941. <a href=\"https://dx.doi.org/10.1038/s41561-022-01053-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01053-7</a>","StandardTitle":"Declining metal availability in the Mesozoic seawater reflected in phytoplankton succession","AuthorsString":"Zhang, Q. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":282630,"RR":"<b>Van Avendonk, H.J.A.; Davis, J.K.; Harding, J.L.; Lawver, L.A.</b> (2017). Decrease in oceanic crustal thickness since the breakup of Pangaea. <i>Nature Geoscience 10(1)</i>: 58-61. <a href=\"http://dx.doi.org/10.1038/ngeo2849\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2849</a>","StandardTitle":"Decrease in oceanic crustal thickness since the breakup of Pangaea","AuthorsString":"Van Avendonk, H.J.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":345728,"RR":"<b>Blackport, R.; Fyfe, J.C.; Screen, J.A.</b> (2021). Decreasing subseasonal temperature variability in the northern extratropics attributed to human influence. <i>Nature Geoscience 14(10)</i>: 719-723. <a href=\"https://dx.doi.org/10.1038/s41561-021-00826-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00826-w</a>","StandardTitle":"Decreasing subseasonal temperature variability in the northern extratropics attributed to human influence","AuthorsString":"Blackport, R.; Fyfe, J.C.; Screen, J.A.","BibLvlCode":"AS"},{"BRefID":294042,"RR":"<b>Andrault, D.; Pesce, G.; Manthilake, G.; Monteux, J.; Bolfan-Casanova, N.; Chantel, J.; Novella, D.; Guignot, N.; King, A.; Itié, J.-P.; Hennet, L.</b> (2018). Deep and persistent melt layer in the Archaean mantle. <i>Nature Geoscience 11(2)</i>: 139-143. <a href=\"https://dx.doi.org/10.1038/s41561-017-0053-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0053-9</a>","StandardTitle":"Deep and persistent melt layer in the Archaean mantle","AuthorsString":"Andrault, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":217875,"RR":"<b>Cronin, T.M.; Dwyer, G.S.; Farmer, J.; Bauch, H.A.; Spielhagen, R.F.; Jakobsson, M.; Nilsson, J.; Briggs Jr., W.M.; Stepanova, A.</b> (2012). Deep Arctic Ocean warming during the last glacial cycle. <i>Nature Geoscience 5(9)</i>: 631-634. <a href=\"http://dx.doi.org/10.1038/ngeo1557\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1557</a>","StandardTitle":"Deep Arctic Ocean warming during the last glacial cycle","AuthorsString":"Cronin, T.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":310826,"RR":"<b>Farmer, J.R.; Hönisch, B.; Haynes, L.L.; Kroon, D.; Jung, S.; Ford, H.L.; Raymo, M.E.; Jaume-Seguí, M.; Bell, D.B.; Goldstein, S.L.; Pena, L.D.; Yehudai, M.; Kim, J.</b> (2019). Deep Atlantic Ocean carbon storage and the rise of 100,000-year glacial cycles. <i>Nature Geoscience 12(5)</i>: 355-360. <a href=\"https://dx.doi.org/10.1038/s41561-019-0334-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0334-6</a>","StandardTitle":"Deep Atlantic Ocean carbon storage and the rise of 100,000-year glacial cycles","AuthorsString":"Farmer, J.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":303730,"RR":"<b>Melgar, D.; Ruiz-Angulo, A.; Garcia, E.S.; Manea, M.; Manea, Vlad. C.; Xu, X.; Ramírez-Herrera, M.T.; Zavala-Hidalgo, J.; Geng, J.; Corona, N.; Pérez-Campos, X.; Cabral-Cano, E.; Ramirez-Guzmán, L.</b> (2018). Deep embrittlement and complete rupture of the lithosphere during the M<sub>w</sub> 8.2 Tehuantepec earthquake. <i>Nature Geoscience 11(12)</i>: 955-960. <a href=\"https://dx.doi.org/10.1038/s41561-018-0229-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0229-y</a>","StandardTitle":"Deep embrittlement and complete rupture of the lithosphere during the M<sub>w</sub> 8.2 Tehuantepec earthquake","AuthorsString":"Melgar, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366510,"RR":"<b>Hastie, A.R.; Law, S.; Bromiley, G.D.; Fitton, J.G.; Harley, S.L.; Muir, D.D.</b> (2023). Deep formation of Earth’s earliest continental crust consistent with subduction. <i>Nature Geoscience 16(9)</i>: 816-821. <a href=\"https://dx.doi.org/10.1038/s41561-023-01249-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01249-5</a>","StandardTitle":"Deep formation of Earth’s earliest continental crust consistent with subduction","AuthorsString":"Hastie, A.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":321494,"RR":"<b>Morlighem, Mathieu; Rignot, Eric; Binder, Tobias; Blankenship, Donald; Drews, Reinhard; Eagles, Graeme; Eisen, Olaf; Ferraccioli, Fausto; Forsberg, René; Fretwell, Peter; Goel, Vikram; Greenbaum, Jamin S.; Gudmundsson, Hilmar; Guo, Jingxue; Helm, Veit; Hofstede, Coen; Howat, Ian; Humbert, Angelika; Jokat, Wilfried; Karlsson, Nanna B.; Lee, Won Sang; Matsuoka, Kenichi; Millan, Romain; Mouginot, Jeremie; Paden, John; Pattyn, Frank; Roberts, Jason; Rosier, Sebastian; Ruppel, Antonia; Seroussi, Helene; Smith, Emma C.; Steinhage, Daniel; Sun, Bo; Broeke, Michiel R. van den; Ommen, Tas D. van; Wessem, Melchior van; Young, Duncan A.</b> (2019). Deep glacial troughs and stabilizing ridges unveiled beneath the margins of the Antarctic ice sheet. <i>Nature Geoscience 13(2)</i>: 132-137. <a href=\"https://dx.doi.org/10.1038/s41561-019-0510-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0510-8</a>","StandardTitle":"Deep glacial troughs and stabilizing ridges unveiled beneath the margins of the Antarctic ice sheet","AuthorsString":"Morlighem, Mathieu <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":419034,"RR":"<b>Deng, J.; Miyazaki, Y.; Yuan, Q.; Du, Z.</b> (2025). Deep mantle heterogeneities formed through a basal magma ocean contaminated by core exsolution. <i>Nature Geoscience 18(10)</i>: 1056-1062. <a href=\"https://dx.doi.org/10.1038/s41561-025-01797-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01797-y</a>","StandardTitle":"Deep mantle heterogeneities formed through a basal magma ocean contaminated by core exsolution","AuthorsString":"Deng, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":393299,"RR":"<b>Deschamps, F.</b> (2024). Deep mantle water prefers slabs. <i>Nature Geoscience 17(7)</i>: 590-591. <a href=\"https://dx.doi.org/10.1038/s41561-024-01468-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01468-4</a>","StandardTitle":"Deep mantle water prefers slabs","AuthorsString":"Deschamps, F.","BibLvlCode":"AS"},{"BRefID":438828,"RR":"<b>Lee, Y.-H.; Yeh, S.-W.; Wang, G.; Song, S.-Y.; An, S.-I.</b> (2026). Deep ocean control of global temperature after net-zero emissions. <i>Nature Geoscience 19(4)</i>: 406-409. <a href=\"https://dx.doi.org/10.1038/s41561-026-01934-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01934-1</a>","StandardTitle":"Deep ocean control of global temperature after net-zero emissions","AuthorsString":"Lee, Y.-H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":283772,"RR":"<b>Homoky, W.B.</b> (2017). Deep ocean iron balance. <i>Nature Geoscience 10(3)</i>: 162-163. <a href=\"http://dx.doi.org/10.1038/ngeo2908\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2908</a>","StandardTitle":"Deep ocean iron balance","AuthorsString":"Homoky, W.B.","BibLvlCode":"AS"},{"BRefID":325386,"RR":"<b>Dürig, T.; White, J.D.L.; Murch, A.P.; Zimanowski, B.; Büttner, R.; Mele, D.; Dellino, P.; Carey, R.J.; Schmidt, L.S.; Spitznagel, N.</b> (2020). Deep-sea eruptions boosted by induced fuel–coolant explosions. <i>Nature Geoscience 13(7)</i>: 498-503. <a href=\"https://dx.doi.org/10.1038/s41561-020-0603-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0603-4</a>","StandardTitle":"Deep-sea eruptions boosted by induced fuel–coolant explosions","AuthorsString":"Dürig, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":301860,"RR":"<b>Anderson, M.O.</b> (2018). Deep-sea ore deposits. <i>Nature Geoscience 11(10)</i>: 706-706. <a href=\"https://dx.doi.org/10.1038/s41561-018-0237-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0237-y</a>","StandardTitle":"Deep-sea ore deposits","AuthorsString":"Anderson, M.O.","BibLvlCode":"AS"},{"BRefID":238943,"RR":"<b>Morlighem, M.; Rignot, E.; Mouginot, J.; Seroussi, H.; Larour, E.</b> (2014). Deeply incised submarine glacial valleys beneath the Greenland ice sheet. <i>Nature Geoscience 7(6)</i>: 418–422. <a href=\"http://dx.doi.org/10.1038/ngeo2167\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2167</a>","StandardTitle":"Deeply incised submarine glacial valleys beneath the Greenland ice sheet","AuthorsString":"Morlighem, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":246329,"RR":"<b>O'Connor, J.M.; Hoernie, K.; Müller, R.D.; Morgan, J.P.; Butterworth, N.P.; Hauff, F.; Sandwell, D.T.; Jokat, W.; Wijbrans, J.R.; Stoffers, P.</b> (2015). Deformation-related volcanism in the Pacific Ocean linked to the Hawaiian–Emperor bend. <i>Nature Geoscience 8(5)</i>: 393–397. <a href=\"http://dx.doi.org/10.1038/ngeo2416\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2416</a>","StandardTitle":"Deformation-related volcanism in the Pacific Ocean linked to the Hawaiian–Emperor bend","AuthorsString":"O'Connor, J.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":252106,"RR":"<b>Tierney, J.E.; Pausata, F.S.R.; deMenocal, P.</b> (2016). Deglacial Indian monsoon failure and North Atlantic stadials linked by Indian Ocean surface cooling. <i>Nature Geoscience 9(1)</i>: 46-50. <a href=\"http://dx.doi.org/10.1038/ngeo2603\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2603</a>","StandardTitle":"Deglacial Indian monsoon failure and North Atlantic stadials linked by Indian Ocean surface cooling","AuthorsString":"Tierney, J.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296264,"RR":"<b>Gray, W.R.; Rae, J.W.B.; Wills, R.C.J.; Shevenell, A.E.; Taylor, B.; Burke, A.; Foster, G.L.; Lear, C.H.</b> (2018). Deglacial upwelling, productivity and CO<sub>2</sub> outgassing in the North Pacific Ocean. <i>Nature Geoscience 11(5)</i>: 340-344. <a href=\"https://dx.doi.org/10.1038/s41561-018-0108-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0108-6</a>","StandardTitle":"Deglacial upwelling, productivity and CO<sub>2</sub> outgassing in the North Pacific Ocean","AuthorsString":"Gray, W.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":414056,"RR":"<b>ten Hietbrink, S.; Patton, H.; Dugan, B.; Szymczycha, B.; Sen, A.; Lepland, A.; Knies, J.; Kim, J.-H.; Chen, N.-C.; Hong, W.-L.</b> (2025). Deglaciation drove seawater infiltration and slowed submarine groundwater discharge. <i>Nature Geoscience 18(8)</i>: 779-786. <a href=\"https://dx.doi.org/10.1038/s41561-025-01750-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01750-z</a>","StandardTitle":"Deglaciation drove seawater infiltration and slowed submarine groundwater discharge","AuthorsString":"ten Hietbrink, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":437762,"RR":"<b>Walcott-George, C.K.; Brown, N.D.; Briner, J.P.; Balter-Kennedy, A.; Young, N.E.; Kuhl, T.; Moravec, E.; Anandakrishnan, S.; Stevens, N.T.; Keisling, B.; DeConto, R.M.; Gkinis, V.; MacGregor, J.A.; Schaefer, J.M.</b> (2026). Deglaciation of the Prudhoe Dome in northwestern Greenland in response to Holocene warming. <i>Nature Geoscience 19(2)</i>: 189-194. <a href=\"https://dx.doi.org/10.1038/s41561-025-01889-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01889-9</a>","StandardTitle":"Deglaciation of the Prudhoe Dome in northwestern Greenland in response to Holocene warming","AuthorsString":"Walcott-George, C.K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":252692,"RR":"<b>Patricola, C.M.; Chang, P.; Saravanan, R.</b> (2015). Degree of simulated suppression of Atlantic tropical cyclones modulated by flavour of El Niño. <i>Nature Geoscience 9(2)</i>: 155-160. <a href=\"http://dx.doi.org/10.1038/ngeo2624\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2624</a>","StandardTitle":"Degree of simulated suppression of Atlantic tropical cyclones modulated by flavour of El Niño","AuthorsString":"Patricola, C.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":260847,"RR":"<b>Nedimovic, M.R.</b> (2016). Delayed response to mantle pull. <i>Nature Geoscience 9(8)</i>: 571-572. <a href=\"http://dx.doi.org/10.1038/ngeo2746\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2746</a>","StandardTitle":"Delayed response to mantle pull","AuthorsString":"Nedimovic, M.R.","BibLvlCode":"AS"},{"BRefID":321492,"RR":"<b>Zou, S.; Lozier, M.S.; Li, F.; Abernathey, R.; Jackson, L.</b> (2020). Density-compensated overturning in the Labrador Sea. <i>Nature Geoscience 13(2)</i>: 121-126. <a href=\"https://dx.doi.org/10.1038/s41561-019-0517-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0517-1</a>","StandardTitle":"Density-compensated overturning in the Labrador Sea","AuthorsString":"Zou, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":348076,"RR":"<b>Boghosian, A.L.; Pitcher, L.H.; Smith, L.C.; Kosh, E.; Alexander, P.M.; Tedesco, M.; Bell, R.E.</b> (2021). Development of ice-shelf estuaries promotes fractures and calving. <i>Nature Geoscience 14(12)</i>: 899-905. <a href=\"https://dx.doi.org/10.1038/s41561-021-00837-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00837-7</a>","StandardTitle":"Development of ice-shelf estuaries promotes fractures and calving","AuthorsString":"Boghosian, A.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":361177,"RR":"(2023). Differential rotation of the Earth’s inner core changes over decades and has come to near-halt. <i>Nature Geoscience 16(2)</i>: 113-114. <a href=\"https://dx.doi.org/10.1038/s41561-022-01113-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01113-y</a>","StandardTitle":"Differential rotation of the Earth’s inner core changes over decades and has come to near-halt","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":359500,"RR":"<b>Neely, R.</b> (2022). Digging into deep water. <i>Nature Geoscience 15(11)</i>: 858-860. <a href=\"https://dx.doi.org/10.1038/s41561-022-01038-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01038-6</a>","StandardTitle":"Digging into deep water","AuthorsString":"Neely, R.","BibLvlCode":"AS"},{"BRefID":347571,"RR":"<b>Zhang, X.; Barker, S.; Knorr, G.; Lohmann, G.; Drysdale, R.; Sun, Y.; Hodell, D.; Chen, F.</b> (2021). Direct astronomical influence on abrupt climate variability. <i>Nature Geoscience 14(11)</i>: 819-826. <a href=\"https://dx.doi.org/10.1038/s41561-021-00846-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00846-6</a>","StandardTitle":"Direct astronomical influence on abrupt climate variability","AuthorsString":"Zhang, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":313845,"RR":"<b>Plaza, C.; Pegoraro, E.; Bracho, R.; Celis, G.; Crummer, K.G.; Hutchings, J.A.; Hicks Pries, C.E.; Mauritz, M.; Natali, S.M.; Salmon, V.G.; Schädel, C.; Webb, E.E.; Schuur, E.A.G.</b> (2019). Direct observation of permafrost degradation and rapid soil carbon loss in tundra. <i>Nature Geoscience 12(8)</i>: 627-631. <a href=\"https://dx.doi.org/10.1038/s41561-019-0387-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0387-6</a>","StandardTitle":"Direct observation of permafrost degradation and rapid soil carbon loss in tundra","AuthorsString":"Plaza, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366128,"RR":"(2023). Disappearance of Arctic sea ice during summers of the Last Interglacial. <i>Nature Geoscience 16(8)</i>: 669-670. <a href=\"https://dx.doi.org/10.1038/s41561-023-01228-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01228-w</a>","StandardTitle":"Disappearance of Arctic sea ice during summers of the Last Interglacial","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":338978,"RR":"<b>Lee, K.; Feely, R.A.</b> (2021). Dissolution resolution. <i>Nature Geoscience 14(6)</i>: 356-357. <a href=\"https://dx.doi.org/10.1038/s41561-021-00765-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00765-6</a>","StandardTitle":"Dissolution resolution","AuthorsString":"Lee, K.; Feely, R.A.","BibLvlCode":"AS"},{"BRefID":354972,"RR":"<b>Liang, Z.; Letscher, R.T.; Knapp, A.N.</b> (2022). Dissolved organic phosphorus concentrations in the surface ocean controlled by both phosphate and iron stress. <i>Nature Geoscience 15(8)</i>: 651-657. <a href=\"https://dx.doi.org/10.1038/s41561-022-00988-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00988-1</a>","StandardTitle":"Dissolved organic phosphorus concentrations in the surface ocean controlled by both phosphate and iron stress","AuthorsString":"Liang, Z.; Letscher, R.T.; Knapp, A.N.","BibLvlCode":"AS"},{"BRefID":367821,"RR":"(2023). Dissolved phosphorus concentrations are increasing in streams across the Great Lakes Basin. <i>Nature Geoscience 16(10)</i>: 841-842. <a href=\"https://dx.doi.org/10.1038/s41561-023-01270-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01270-8</a>","StandardTitle":"Dissolved phosphorus concentrations are increasing in streams across the Great Lakes Basin","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":437759,"RR":"<b>Le Coq, Pauline; Christaki, Urania; Van Wambeke, France; Chevillon, Elisabeth; Zakardjian, Bruno; Garel, Marc; Guasco, Sophie; Baumas, Chloé M. J.; Dekas, Anne E.; Bonin, Patricia; Ali, Badr Al; Gesson, Maéva; Le Moigne, Frédéric; Pujo-Pay, Mireille; Crispi, Olivier; Grosso, Olivier; Moutin, Thierry; Bhairy, Nagib; de Saint Léger, Emmanuel; Memery, Laurent; Guidi, Lionel; Armougom, Fabrice; Grossart, Hans-Peter; Tamburini, Christian</b> (2026). Distinct contributions of suspended and sinking prokaryotes to mesopelagic carbon budget. <i>Nature Geoscience 19(2)</i>: 165-172. <a href=\"https://dx.doi.org/10.1038/s41561-025-01888-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01888-w</a>","StandardTitle":"Distinct contributions of suspended and sinking prokaryotes to mesopelagic carbon budget","AuthorsString":"Le Coq, Pauline <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":325387,"RR":"<b>Doucet, L.S.; Li, E.-X.; Gamal El Dien, H.; Pourteau, A.; Murphy, J.B.; Collins, W.J.; Mattielli, N.; Olierook, H.K.H.; Spencer, C.J.; Mitchell, R.N.</b> (2020). Distinct formation history for deep-mantle domains reflected in geochemical differences. <i>Nature Geoscience 13(7)</i>: 511-515. <a href=\"https://dx.doi.org/10.1038/s41561-020-0599-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0599-9</a>","StandardTitle":"Distinct formation history for deep-mantle domains reflected in geochemical differences","AuthorsString":"Doucet, L.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":331731,"RR":"<b>Wang, X.; Chen, Q.-F.; Niu, F.; Wei, S.; Ning, J.; Li, J.; Wang, W.; Buchen, J.; Liu, L.</b> (2020). Distinct slab interfaces imaged within the mantle transition zone. <i>Nature Geoscience 13(12)</i>: 822-827. <a href=\"https://dx.doi.org/10.1038/s41561-020-00653-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00653-5</a>","StandardTitle":"Distinct slab interfaces imaged within the mantle transition zone","AuthorsString":"Wang, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":339837,"RR":"<b>Kostov, Y.; Johnson, H.L.; Marshall, D.P.; Heimbach, P.; Forget, G.; Holliday, N.P.; Lozier, M.S.; Li, F.; Pillar, H.R.; Smith, T.</b> (2021). Distinct sources of interannual subtropical and subpolar Atlantic overturning variability. <i>Nature Geoscience 14(7)</i>: 491–495. <a href=\"https://dx.doi.org/10.1038/s41561-021-00759-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00759-4</a>","StandardTitle":"Distinct sources of interannual subtropical and subpolar Atlantic overturning variability","AuthorsString":"Kostov, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":391798,"RR":"<b>Cronin, M.F.; Zhang, D.; Wills, S.M.; Reeves Eyre, J.E.J.; Thompson, L.; Anderson, N.</b> (2024). Diurnal warming rectification in the tropical Pacific linked to sea surface temperature front. <i>Nature Geoscience 17(4)</i>: 316-322. <a href=\"https://dx.doi.org/10.1038/s41561-024-01391-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01391-8</a>","StandardTitle":"Diurnal warming rectification in the tropical Pacific linked to sea surface temperature front","AuthorsString":"Cronin, M.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359756,"RR":"<b>Barge, L.M.; Price, R.E.</b> (2022). Diverse geochemical conditions for prebiotic chemistry in shallow-sea alkaline hydrothermal vents. <i>Nature Geoscience 15(12)</i>: 976-981. <a href=\"https://dx.doi.org/10.1038/s41561-022-01067-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01067-1</a>","StandardTitle":"Diverse geochemical conditions for prebiotic chemistry in shallow-sea alkaline hydrothermal vents","AuthorsString":"Barge, L.M.; Price, R.E.","BibLvlCode":"AS"},{"BRefID":408007,"RR":"<b>Zhang, N.; Li, H.; Xu, F.; Thompson, C.E.L.; Townend, I.H.; He, Q.</b> (2025). Drag acting on suspended sediment increased by microbial colonization. <i>Nature Geoscience 18(5)</i>: 396-401. <a href=\"https://dx.doi.org/10.1038/s41561-025-01679-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01679-3</a>","StandardTitle":"Drag acting on suspended sediment increased by microbial colonization","AuthorsString":"Zhang, N. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":320562,"RR":"<b>Cesca, S.; Letort, J.; Razafindrakoto, H.N.T.; Heimann, S.; Rivalta, E.; Isken, M.P.; Nikkhoo, M.; Passarelli, L.; Petersen, G.M.; Cotton, F.; Dahm, T.</b> (2020). Drainage of a deep magma reservoir near Mayotte inferred from seismicity and deformation. <i>Nature Geoscience 13(1)</i>: 87-93. <a href=\"https://dx.doi.org/10.1038/s41561-019-0505-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0505-5</a>","StandardTitle":"Drainage of a deep magma reservoir near Mayotte inferred from seismicity and deformation","AuthorsString":"Cesca, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":436561,"RR":"<b>Zhang, Y.; Barnes, B.B.; Goodwin, D.S.; Siuda, A.N.S.; Schell, J.M.; McGillicuddy, D.J.; Lapointe, B.E.; Qi, L.; Hu, C.</b> (2025). Dramatic decline of <i>Sargassum</i> in the north Sargasso Sea since 2015. <i>Nature Geoscience 18(12)</i>: 1266-1272. <a href=\"https://dx.doi.org/10.1038/s41561-025-01863-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01863-5</a>","StandardTitle":"Dramatic decline of <i>Sargassum</i> in the north Sargasso Sea since 2015","AuthorsString":"Zhang, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":298377,"RR":"<b>Oschlies, A.; Brandt, P.; Stramma, L.; Schmidtko, S.</b> (2018). Drivers and mechanisms of ocean deoxygenation. <i>Nature Geoscience 11(7)</i>: 467-473. <a href=\"https://dx.doi.org/10.1038/s41561-018-0152-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0152-2</a>","StandardTitle":"Drivers and mechanisms of ocean deoxygenation","AuthorsString":"Oschlies, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":333778,"RR":"<b>Blanchet, C.L.; Osborne, A.H.; Tjallingii, R.; Ehrmann, W.; Friedrich, T.; Timmermann, A.; Brückmann, W.; Frank, M.</b> (2021). Drivers of river reactivation in North Africa during the last glacial cycle. <i>Nature Geoscience 14(2)</i>: 97-103. <a href=\"https://dx.doi.org/10.1038/s41561-020-00671-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00671-3</a>","StandardTitle":"Drivers of river reactivation in North Africa during the last glacial cycle","AuthorsString":"Blanchet, C.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":341630,"RR":"<b>Sato, H.; Kelley, D.I.; Mayor, S.J.; Martin Calvo, M.; Cowling, S.A.; Prentice, I.C.</b> (2021). Dry corridors opened by fire and low CO<sub>2</sub> in Amazonian rainforest during the Last Glacial Maximum. <i>Nature Geoscience 14(8)</i>: 578-585. <a href=\"https://dx.doi.org/10.1038/s41561-021-00777-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00777-2</a>","StandardTitle":"Dry corridors opened by fire and low CO<sub>2</sub> in Amazonian rainforest during the Last Glacial Maximum","AuthorsString":"Sato, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":290730,"RR":"<b>Canales, J.P.; Carbotte, S.M.; Nedimovic, M.R.; Carton, H.</b> (2017). Dry Juan de Fuca slab revealed by quantification of water entering Cascadia subduction zone. <i>Nature Geoscience 10(11)</i>: 864-870. <a href=\"https://dx.doi.org/10.1038/ngeo3050\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3050</a>","StandardTitle":"Dry Juan de Fuca slab revealed by quantification of water entering Cascadia subduction zone","AuthorsString":"Canales, J.P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":337903,"RR":"<b>Gillmann, C.; Golabek, G.J.; Raymond, S.N.; Schönbächler, M.; Tackley, P.J.; Dehant, V.; Debaille, V.</b> (2020). Dry late accretion inferred from Venus's coupled atmosphere and internal evolution. <i>Nature Geoscience 13(4)</i>: 265-269. <a href=\"https://hdl.handle.net/10.1038/s41561-020-0561-x\" target=\"_blank\">https://hdl.handle.net/10.1038/s41561-020-0561-x</a>","StandardTitle":"Dry late accretion inferred from Venus's coupled atmosphere and internal evolution","AuthorsString":"Gillmann, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359506,"RR":"(2022). Dust emission increases following large wildfires. <i>Nature Geoscience 15(11)</i>: 867-868. <a href=\"https://dx.doi.org/10.1038/s41561-022-01047-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01047-5</a>","StandardTitle":"Dust emission increases following large wildfires","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":437756,"RR":"<b>Fourquez, M.</b> (2026). Dusting off the iron hypothesis. <i>Nature Geoscience 19(2)</i>: 130-131. <a href=\"https://dx.doi.org/10.1038/s41561-025-01913-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01913-y</a>","StandardTitle":"Dusting off the iron hypothesis","AuthorsString":"Fourquez, M.","BibLvlCode":"AS"},{"BRefID":287582,"RR":"<b>Matthews, J.P.; Ostrovsky, L.; Yoshikawa, Y.; Komori, S.; Tamura, H.</b> (2017). Dynamics and early post-tsunami evolution of floating marine debris near Fukushima Daiichi. <i>Nature Geoscience 10(8)</i>: 598-603. <a href=\"https://dx.doi.org/10.1038/ngeo2975\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2975</a>","StandardTitle":"Dynamics and early post-tsunami evolution of floating marine debris near Fukushima Daiichi","AuthorsString":"Matthews, J.P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":349093,"RR":"<b>Hu, J.; Gurnis, M.; Rudi, J.; Stadler, G.; Müller, R.D.</b> (2022). Dynamics of the abrupt change in Pacific Plate motion around 50 million years ago. <i>Nature Geoscience 15(1)</i>: 74-78. <a href=\"https://dx.doi.org/10.1038/s41561-021-00862-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00862-6</a>","StandardTitle":"Dynamics of the abrupt change in Pacific Plate motion around 50 million years ago","AuthorsString":"Hu, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":245788,"RR":"<b>Yan, H.; Wei, W.; Soon, W.; An, Z.; Zhou, W.; Liu, Z.; Wang, Y.; Carter, R.M.</b> (2015). Dynamics of the intertropical convergence zone over the western Pacific during the Little Ice Age. <i>Nature Geoscience 8(4)</i>: 315–320. <a href=\"http://dx.doi.org/10.1038/ngeo2375\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2375</a>","StandardTitle":"Dynamics of the intertropical convergence zone over the western Pacific during the Little Ice Age","AuthorsString":"Yan, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":438183,"RR":"<b>Muis, S.</b> (2026). Early action for coastal communities. <i>Nature Geoscience 19(3)</i>: 239-240. <a href=\"https://dx.doi.org/10.1038/s41561-026-01932-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01932-3</a>","StandardTitle":"Early action for coastal communities","AuthorsString":"Muis, S.","BibLvlCode":"AS"},{"BRefID":356616,"RR":"<b>Shen, J.; Zhang, Y.G.; Yang, H.; Xie, S.; Pearson, A.</b> (2022). Early and late phases of the Permian–Triassic mass extinction marked by different atmospheric CO<sub>2</sub> regimes. <i>Nature Geoscience 15(10)</i>: 839-844. <a href=\"https://dx.doi.org/10.1038/s41561-022-01034-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01034-w</a>","StandardTitle":"Early and late phases of the Permian–Triassic mass extinction marked by different atmospheric CO<sub>2</sub> regimes","AuthorsString":"Shen, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":308745,"RR":"<b>Bao, H.; Ampuero, J.-P.; Meng, L.; Fielding, E.J.; Liang, C.; Milliner, C.W.D.; Feng, T.; Huang, H.</b> (2019). Early and persistent supershear rupture of the 2018 magnitude 7.5 Palu earthquake. <i>Nature Geoscience 12(3)</i>: 200-205. <a href=\"https://dx.doi.org/10.1038/s41561-018-0297-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0297-z</a>","StandardTitle":"Early and persistent supershear rupture of the 2018 magnitude 7.5 Palu earthquake","AuthorsString":"Bao, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":408000,"RR":"<b>Caro, G.; Grocolas, T.; Bourgeois, P.; Bouilhol, P.; Mojzsis, S.J.; Paris, G.</b> (2025). Early Archaean onset of volatile cycling at subduction zones. <i>Nature Geoscience 18(5)</i>: 436-442. <a href=\"https://dx.doi.org/10.1038/s41561-025-01677-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01677-5</a>","StandardTitle":"Early Archaean onset of volatile cycling at subduction zones","AuthorsString":"Caro, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":316666,"RR":"<b>André, L.; Abraham, K.; Hofmann, A.; Monin, L.; Kleinhanns, I.C.; Foley, S.</b> (2019). Early continental crust generated by reworking of basalts variably silicified by seawater. <i>Nature Geoscience 12(9)</i>: 769-773. <a href=\"https://dx.doi.org/10.1038/s41561-019-0408-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0408-5</a>","StandardTitle":"Early continental crust generated by reworking of basalts variably silicified by seawater","AuthorsString":"André, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":290732,"RR":"<b>Byerly, B.L.; Kareem, K.; Bao, H.; Byerly, G.R.</b> (2017). Early Earth mantle heterogeneity revealed by light oxygen isotopes of Archaean komatiites. <i>Nature Geoscience 10(11)</i>: 871-875. <a href=\"https://dx.doi.org/10.1038/ngeo3054\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3054</a>","StandardTitle":"Early Earth mantle heterogeneity revealed by light oxygen isotopes of Archaean komatiites","AuthorsString":"Byerly, B.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":368757,"RR":"<b>Dutta, D.; Jucker, M.; Sherwood, S.C.; Meissner, K.J.; Sen Gupta, A.; Zhu, J.</b> (2023). Early Eocene low orography and high methane enhance Arctic warming via polar stratospheric clouds. <i>Nature Geoscience 16(11)</i>: 1027-1032. <a href=\"https://dx.doi.org/10.1038/s41561-023-01298-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01298-w</a>","StandardTitle":"Early Eocene low orography and high methane enhance Arctic warming via polar stratospheric clouds","AuthorsString":"Dutta, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":391171,"RR":"<b>Fendley, I.M.; Frieling, J.; Mather, T.A.; Ruhl, M.; Hesselbo, S.P.; Jenkyns, H.C.</b> (2024). Early Jurassic large igneous province carbon emissions constrained by sedimentary mercury. <i>Nature Geoscience 17(3)</i>: 241-248. <a href=\"https://dx.doi.org/10.1038/s41561-024-01378-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01378-5</a>","StandardTitle":"Early Jurassic large igneous province carbon emissions constrained by sedimentary mercury","AuthorsString":"Fendley, I.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":283193,"RR":"<b>Poulton, S.W.</b> (2017). Early phosphorus redigested. <i>Nature Geoscience 10(2)</i>: 75-76. <a href=\"http://dx.doi.org/10.1038/ngeo2884\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2884</a>","StandardTitle":"Early phosphorus redigested","AuthorsString":"Poulton, S.W.","BibLvlCode":"AS"},{"BRefID":360456,"RR":"<b>Yan, Y.; Kurbatov, A.V.; Mayewski, P.A.; Shackleton, S.; Higgins, J.A.</b> (2023). Early Pleistocene East Antarctic temperature in phase with local insolation. <i>Nature Geoscience 16(1)</i>: 50-55. <a href=\"https://dx.doi.org/10.1038/s41561-022-01095-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01095-x</a>","StandardTitle":"Early Pleistocene East Antarctic temperature in phase with local insolation","AuthorsString":"Yan, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":408002,"RR":"<b>Hoffmann, J.E.</b> (2025). Early start to volatile cycling. <i>Nature Geoscience 18(5)</i>: 374-375. <a href=\"https://dx.doi.org/10.1038/s41561-025-01689-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01689-1</a>","StandardTitle":"Early start to volatile cycling","AuthorsString":"Hoffmann, J.E.","BibLvlCode":"AS"},{"BRefID":361136,"RR":"<b>Barnard, P.L.; Vitousek, S.</b> (2023). Earth science looks to outer space. <i>Nature Geoscience 16(2)</i>: 108-109. <a href=\"https://dx.doi.org/10.1038/s41561-023-01123-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01123-4</a>","StandardTitle":"Earth science looks to outer space","AuthorsString":"Barnard, P.L.; Vitousek, S.","BibLvlCode":"AS"},{"BRefID":435872,"RR":"<b>Willeit, M.; Ganopolski, A.; Kaufhold, C.; Dalmonech, D.; Liu, B.; Ilyina, T.</b> (2025). Earth system response to Heinrich events explained by a bipolar convection seesaw. <i>Nature Geoscience 18(11)</i>: 1159-1166. <a href=\"https://dx.doi.org/10.1038/s41561-025-01814-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01814-0</a>","StandardTitle":"Earth system response to Heinrich events explained by a bipolar convection seesaw","AuthorsString":"Willeit, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":289770,"RR":"<b>Smit, M.A.; Mezger, K.</b> (2017). Earth’s early O<sub>2</sub> cycle suppressed by primitive continents. <i>Nature Geoscience 10(10)</i>: 788-792. <a href=\"https://dx.doi.org/10.1038/ngeo3030\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3030</a>","StandardTitle":"Earth’s early O<sub>2</sub> cycle suppressed by primitive continents","AuthorsString":"Smit, M.A.; Mezger, K.","BibLvlCode":"AS"},{"BRefID":408329,"RR":"<b>Pinti, D.L.</b> (2025). Earth’s exhale. <i>Nature Geoscience 18(6)</i>: 452-453. <a href=\"https://dx.doi.org/10.1038/s41561-025-01710-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01710-7</a>","StandardTitle":"Earth’s exhale","AuthorsString":"Pinti, D.L.","BibLvlCode":"AS"},{"BRefID":350629,"RR":"<b>Alcott, L.J.; Mills, B.J.W.; Bekker, A.; Poulton, S.W.</b> (2022). Earth’s Great Oxidation Event facilitated by the rise of sedimentary phosphorus recycling. <i>Nature Geoscience 15</i>: 210-215. <a href=\"https://dx.doi.org/10.1038/s41561-022-00906-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00906-5</a>","StandardTitle":"Earth’s Great Oxidation Event facilitated by the rise of sedimentary phosphorus recycling","AuthorsString":"Alcott, L.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":334822,"RR":"<b>Goldblatt, C.; McDonald, V.L.; McCusker, K.E.</b> (2021). Earth’s long-term climate stabilized by clouds. <i>Nature Geoscience 14(3)</i>: 143-150. <a href=\"https://dx.doi.org/10.1038/s41561-021-00691-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00691-7</a>","StandardTitle":"Earth’s long-term climate stabilized by clouds","AuthorsString":"Goldblatt, C.; McDonald, V.L.; McCusker, K.E.","BibLvlCode":"AS"},{"BRefID":349094,"RR":"<b>Tucker, J.M.; van Keken, P.E.; Ballentine, C.J.</b> (2022). Earth’s missing argon paradox resolved by recycling of oceanic crust. <i>Nature Geoscience 15(1)</i>: 85-90. <a href=\"https://dx.doi.org/10.1038/s41561-021-00870-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00870-6</a>","StandardTitle":"Earth’s missing argon paradox resolved by recycling of oceanic crust","AuthorsString":"Tucker, J.M.; van Keken, P.E.; Ballentine, C.J.","BibLvlCode":"AS"},{"BRefID":436652,"RR":"<b>Trapp-Müller, G.; Caves Rugenstein, J.K.; Conley, D.J.; Geilert, S.; Hagens, M.; Hong, W.-L.; Jeandel, C.; Longman, J.; Mason, P.R.D.; Middelburg, J.J.; Milliken, K.L.; Navarre-Sitchler, A.; Planavsky, N.J.; Reichart, G.-J.; Slomp, C.P.; Sluijs, A.; Van Hinsbergen, D.J.J.; Zhang, X.</b> (2025). Earth’s silicate weathering continuum. <i>Nature Geoscience 18(8)</i>: 691-701. <a href=\"https://dx.doi.org/10.1038/s41561-025-01743-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01743-y</a>","StandardTitle":"Earth’s silicate weathering continuum","AuthorsString":"Trapp-Müller, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":243201,"RR":"<b>Nishikawa, T.; Ide, S.</b> (2014). Earthquake size distribution in subduction zones linked to slab buoyancy. <i>Nature Geoscience 7(12)</i>: 904–908. <a href=\"http://dx.doi.org/10.1038/ngeo2279\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2279</a>","StandardTitle":"Earthquake size distribution in subduction zones linked to slab buoyancy","AuthorsString":"Nishikawa, T.; Ide, S.","BibLvlCode":"AS"},{"BRefID":323342,"RR":"<b>Cummins, P.R.; Pranantyo, I.R.; Pownall, J.M.; Griffin, J.D.; Meilano, I.; Zhao, S.</b> (2020). Earthquakes and tsunamis caused by low-angle normal faulting in the Banda Sea, Indonesia. <i>Nature Geoscience 13(4)</i>: 312-318. <a href=\"https://dx.doi.org/10.1038/s41561-020-0545-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0545-x</a>","StandardTitle":"Earthquakes and tsunamis caused by low-angle normal faulting in the Banda Sea, Indonesia","AuthorsString":"Cummins, P.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":243204,"RR":"<b>Thompson, A.F.; Heywood, K.J.; Schmidtko, S.; Stewart, A.L.</b> (2014). Eddy transport as a key component of the Antarctic overturning circulation. <i>Nature Geoscience 7(12)</i>: 879–884. <a href=\"http://dx.doi.org/10.1038/ngeo2289\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2289</a>","StandardTitle":"Eddy transport as a key component of the Antarctic overturning circulation","AuthorsString":"Thompson, A.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":240069,"RR":"<b>Sheen, K.L.; Naveira Garabato, A.C.; Brearly, J.A.; Meredith, M.P.; Polzin, K.L.; Smeed, D.A.; Forryan, A.; King, B.A.; Sallée, J.-B.; St. Laurent, L.; Thurnherr, A.M.; Toole, J.M.; Waterman, S.N.; Watson, A.J.</b> (2014). Eddy-induced variability in Southern Ocean abyssal mixing on climatic timescales. <i>Nature Geoscience 7(8)</i>: 577-582. <a href=\"http://dx.doi.org/10.1038/ngeo2200\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2200</a>","StandardTitle":"Eddy-induced variability in Southern Ocean abyssal mixing on climatic timescales","AuthorsString":"Sheen, K.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":250813,"RR":"<b>Hawkes, J.A.; Rossel, P.E.; Stubbins, A.; Butterfield, D.; Connelly, D.P.; Achterberg, E.P.; Koschinsky, A.; Chavagnac, V.; Hansen, C.T.; Bach, W.; Dittmar, T.</b> (2015). Efficient removal of recalcitrant deep-ocean dissolved organic matter during hydrothermal circulation. <i>Nature Geoscience 8(11)</i>: 856-+. <a href=\"http://dx.doi.org/10.1038/ngeo2543\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2543</a>","StandardTitle":"Efficient removal of recalcitrant deep-ocean dissolved organic matter during hydrothermal circulation","AuthorsString":"Hawkes, J.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":349757,"RR":"<b>Wang, S.; Jing, Z.; Wu, L.; Cai, W.; Chang, P.; Wang, H.; Geng, T.; Danabasoglu, G.; Chen, Z.; Ma, X.; Gan, B.; Yang, H.</b> (2022). El Niño/Southern Oscillation inhibited by submesoscale ocean eddies. <i>Nature Geoscience 15(2)</i>: 112-117. <a href=\"https://dx.doi.org/10.1038/s41561-021-00890-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00890-2</a>","StandardTitle":"El Niño/Southern Oscillation inhibited by submesoscale ocean eddies","AuthorsString":"Wang, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":367910,"RR":"<b>Lachniet, M.S.; Du, X.; Dee, S.G.; Asmerom, Y.; Polyak, V.J.; Tobin, B.W.</b> (2023). Elevated Grand Canyon groundwater recharge during the warm Early Holocene. <i>Nature Geoscience 16(10)</i>: 915-921. <a href=\"https://dx.doi.org/10.1038/s41561-023-01272-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01272-6</a>","StandardTitle":"Elevated Grand Canyon groundwater recharge during the warm Early Holocene","AuthorsString":"Lachniet, M.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":415775,"RR":"<b>Glaubke, R.H.; Sikes, E.L.; Sosdian, S.M.; Umling, N.E.; Starr, A.; Moffa-Sanchez, P.L.; Schmidt, M.W.</b> (2025). Elevated shallow water salinity in the deglacial Indian Ocean was sourced from the deep. <i>Nature Geoscience 18(9)</i>: 893-900. <a href=\"https://dx.doi.org/10.1038/s41561-025-01756-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01756-7</a>","StandardTitle":"Elevated shallow water salinity in the deglacial Indian Ocean was sourced from the deep","AuthorsString":"Glaubke, R.H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":310827,"RR":"<b>Knutz, P.C.; Newton, A.M.W.; Hopper, J.R.; Huuse, M.; Gregersen, U.; Sheldon, E.; Dybkjær, K.</b> (2019). Eleven phases of Greenland Ice Sheet shelf-edge advance over the past 2.7 million years. <i>Nature Geoscience 12(5)</i>: 361-368. <a href=\"https://dx.doi.org/10.1038/s41561-019-0340-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0340-8</a>","StandardTitle":"Eleven phases of Greenland Ice Sheet shelf-edge advance over the past 2.7 million years","AuthorsString":"Knutz, P.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":252107,"RR":"<b>Palin, R.M.; White, R.W.</b> (2016). Emergence of blueschists on Earth linked to secular changes in oceanic crust composition. <i>Nature Geoscience 9(1)</i>: 60-64. <a href=\"http://dx.doi.org/10.1038/ngeo2605\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2605</a>","StandardTitle":"Emergence of blueschists on Earth linked to secular changes in oceanic crust composition","AuthorsString":"Palin, R.M.; White, R.W.","BibLvlCode":"AS"},{"BRefID":289161,"RR":"<b>Chowdhury, P.; Gerya, T.; Chakraborty, S.</b> (2017). Emergence of silicic continents as the lower crust peels off on a hot plate-tectonic Earth. <i>Nature Geoscience 10(9)</i>: 698-703. <a href=\"https://dx.doi.org/10.1038/ngeo3010\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3010</a>","StandardTitle":"Emergence of silicic continents as the lower crust peels off on a hot plate-tectonic Earth","AuthorsString":"Chowdhury, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":368759,"RR":"<b>Hu, Y.; Li, X.; Boos, W.R.; Guo, J.; Lan, J.; Lin, Q.; Han, J.; Zhang, J.; Bao, X.; Yuan, S.; Wei, Q.; Liu, Y.; Yang, J.; Nie, J.; Guo, Z.</b> (2023). Emergence of the modern global monsoon from the Pangaea megamonsoon set by palaeogeography. <i>Nature Geoscience 16(11)</i>: 1041-1046. <a href=\"https://dx.doi.org/10.1038/s41561-023-01288-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01288-y</a>","StandardTitle":"Emergence of the modern global monsoon from the Pangaea megamonsoon set by palaeogeography","AuthorsString":"Hu, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":318160,"RR":"<b>Jiménez-de-la-Cuesta, D.; Mauritsen, T.</b> (2019). Emergent constraints on Earth’s transient and equilibrium response to doubled CO<sub>2</sub> from post-1970s global warming. <i>Nature Geoscience 12(11)</i>: 902-905. <a href=\"https://dx.doi.org/10.1038/s41561-019-0463-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0463-y</a>","StandardTitle":"Emergent constraints on Earth’s transient and equilibrium response to doubled CO<sub>2</sub> from post-1970s global warming","AuthorsString":"Jiménez-de-la-Cuesta, D.; Mauritsen, T.","BibLvlCode":"AS"},{"BRefID":259367,"RR":"<b>Böning, C.W.; Behrens, E.; Biastoch, A.; Getzlaff, K.; Bamber, J.L.</b> (2016). Emerging impact of Greenland meltwater on deepwater formation in the North Atlantic Ocean. <i>Nature Geoscience 9(7)</i>: 523-527. <a href=\"http://dx.doi.org/10.1038/ngeo2740\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2740</a>","StandardTitle":"Emerging impact of Greenland meltwater on deepwater formation in the North Atlantic Ocean","AuthorsString":"Böning, C.W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":289762,"RR":"<b>Millar, R.J.; Fuglestvedt, J.S.; Friedlingstein, P.; Rogelj, J.; Grubb, M.J.; Matthews, H.D.; Skeie, R.B.; Forster, P.M.; Frame, D.J.; Allen, M.R.</b> (2017). Emission budgets and pathways consistent with limiting warming to 1.5 °C. <i>Nature Geoscience 10(10)</i>: 741-747. <a href=\"https://dx.doi.org/10.1038/ngeo3031\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3031</a>","StandardTitle":"Emission budgets and pathways consistent with limiting warming to 1.5 °C","AuthorsString":"Millar, R.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":347578,"RR":"<b>Hülse, D.; Lau, K.V.; van de Velde, S.J.; Arndt, S.; Meyer, K.M.; Ridgwell, A.</b> (2021). End-Permian marine extinction due to temperature-driven nutrient recycling and euxinia. <i>Nature Geoscience 14(11)</i>: 862-867. <a href=\"https://dx.doi.org/10.1038/s41561-021-00829-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00829-7</a>","StandardTitle":"End-Permian marine extinction due to temperature-driven nutrient recycling and euxinia","AuthorsString":"Hülse, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":333779,"RR":"<b>Gunthe, Sachin S.; Liu, Pengfei; Panda, Upasana; Raj, Subha S.; Sharma, Amit; Darbyshire, Eoghan; Reyes-Villegas, Ernesto; Allan, James; Chen, Ying; Wang, Xuan; Song, Shaojie; Pöhlker, Mira L.; Shi, Liuhua; Wang, Yu; Kommula, Snehitha M.; Liu, Tianjia; Ravikrishna, R.; McFiggans, Gordon; Mickley, Loretta J.; Martin, Scot T.; Pöschl, Ulrich; Andreae, Meinrat O.; Coe, Hugh</b> (2021). Enhanced aerosol particle growth sustained by high continental chlorine emission in India. <i>Nature Geoscience 14(2)</i>: 77-84. <a href=\"https://dx.doi.org/10.1038/s41561-020-00677-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00677-x</a>","StandardTitle":"Enhanced aerosol particle growth sustained by high continental chlorine emission in India","AuthorsString":"Gunthe, Sachin S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":253975,"RR":"<b>Krasting, J.P.; Dunne, J.P.; Stouffer, R.J.; Hallberg, R.W.</b> (2016). Enhanced Atlantic sea-level rise relative to the Pacific under high carbon emission rates. <i>Nature Geoscience 9(3)</i>: 210-214. <a href=\"http://dx.doi.org/10.1038/ngeo2641\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2641</a>","StandardTitle":"Enhanced Atlantic sea-level rise relative to the Pacific under high carbon emission rates","AuthorsString":"Krasting, J.P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366133,"RR":"<b>Krause, A.J.; Sluijs, A.; van der Ploeg, R.; Lenton, T.M.; Pogge von Strandmann, P.A.E.</b> (2023). Enhanced clay formation key in sustaining the Middle Eocene Climatic Optimum. <i>Nature Geoscience 16(8)</i>: 730-738. <a href=\"https://dx.doi.org/10.1038/s41561-023-01234-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01234-y</a>","StandardTitle":"Enhanced clay formation key in sustaining the Middle Eocene Climatic Optimum","AuthorsString":"Krause, A.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359507,"RR":"<b>Yu, Y.; Ginoux, P.</b> (2022). Enhanced dust emission following large wildfires due to vegetation disturbance. <i>Nature Geoscience 15(11)</i>: 878-884. <a href=\"https://dx.doi.org/10.1038/s41561-022-01046-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01046-6</a>","StandardTitle":"Enhanced dust emission following large wildfires due to vegetation disturbance","AuthorsString":"Yu, Y.; Ginoux, P.","BibLvlCode":"AS"},{"BRefID":396659,"RR":"<b>Ford, D.J.; Shutler, J.D.; Blanco-Sacristán, J.; Corrigan, S.; Bell, T.G.; Yang, M.; Kitidis, V.; Nightingale, P.D.; Brown, I.; Wimmer, W.; Woolf, D.K.; Casal, T.; Donlon, C.; Tilstone, G.H.; Ashton, I.</b> (2024). Enhanced ocean CO<sub>2</sub> uptake due to near-surface temperature gradients. <i>Nature Geoscience 17(11)</i>: 1135-1140. <a href=\"https://dx.doi.org/10.1038/s41561-024-01570-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01570-7</a>","StandardTitle":"Enhanced ocean CO<sub>2</sub> uptake due to near-surface temperature gradients","AuthorsString":"Ford, D.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291299,"RR":"<b>Tamarin-Brodsky, T.; Kaspi, Y.</b> (2017). Enhanced poleward propagation of storms under climate change. <i>Nature Geoscience 10(12)</i>: 908-913. <a href=\"https://dx.doi.org/10.1038/s41561-017-0001-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0001-8</a>","StandardTitle":"Enhanced poleward propagation of storms under climate change","AuthorsString":"Tamarin-Brodsky, T.; Kaspi, Y.","BibLvlCode":"AS"},{"BRefID":253977,"RR":"<b>Duprat, L.P.A.M.; Bigg, G.R.; Wilton, D.J.</b> (2016). Enhanced Southern Ocean marine productivity due to fertilization by giant icebergs. <i>Nature Geoscience 9(3)</i>: 219-221. <a href=\"http://dx.doi.org/10.1038/ngeo2633\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2633</a>","StandardTitle":"Enhanced Southern Ocean marine productivity due to fertilization by giant icebergs","AuthorsString":"Duprat, L.P.A.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":320545,"RR":"<b>Siegelman, L.; Klein, P.; Rivière, P.; Thompson, A.F.; Torres, H.S.; Flexas, M.; Menemenlis, D.</b> (2020). Enhanced upward heat transport at deep submesoscale ocean fronts. <i>Nature Geoscience 13(1)</i>: 50-55. <a href=\"https://dx.doi.org/10.1038/s41561-019-0489-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0489-1</a>","StandardTitle":"Enhanced upward heat transport at deep submesoscale ocean fronts","AuthorsString":"Siegelman, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":283781,"RR":"<b>Elsworth, G.; Galbraith, E.D.; Halverson, G.P.; Yang, S.</b> (2017). Enhanced weathering and CO<sub>2</sub> drawdown caused by latest Eocene strengthening of the Atlantic meridional overturning circulation. <i>Nature Geoscience 10(3)</i>: 213-216. <a href=\"http://dx.doi.org/10.1038/ngeo2888\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2888</a>","StandardTitle":"Enhanced weathering and CO<sub>2</sub> drawdown caused by latest Eocene strengthening of the Atlantic meridional overturning circulation","AuthorsString":"Elsworth, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":415755,"RR":"<b>O'Connor, G.K.; Nakayama, Y.; Steig, E.J.; Armour, K.C.; Thompson, L.; Hyogo, S.; Berdahl, M.; Shimada, T.</b> (2025). Enhanced West Antarctic ice loss triggered by polynya response to meridional winds. <i>Nature Geoscience 18(9)</i>: 840–847","StandardTitle":"Enhanced West Antarctic ice loss triggered by polynya response to meridional winds","AuthorsString":"O'Connor, G.K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":436569,"RR":"<b>Gernon, T.M.; Brune, S.; Hincks, T.K.; Palmer, M.R.; Spencer, C.J.; Watts, E.J.; Glerum, A.</b> (2025). Enriched mantle generated through persistent convective erosion of continental roots. <i>Nature Geoscience 18(12)</i>: 1311-1318. <a href=\"https://dx.doi.org/10.1038/s41561-025-01843-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01843-9</a>","StandardTitle":"Enriched mantle generated through persistent convective erosion of continental roots","AuthorsString":"Gernon, T.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":415774,"RR":"<b>Ma, H.; Thompson, A.; Hallam, S.J.; Wang, J.; Xiao, Y.; Liu, C.Q.; Chen, C.</b> (2025). Enrichment of metastable iron minerals in global coastal wetlands. <i>Nature Geoscience 18(9)</i>: 885-892. <a href=\"https://dx.doi.org/10.1038/s41561-025-01764-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01764-7</a>","StandardTitle":"Enrichment of metastable iron minerals in global coastal wetlands","AuthorsString":"Ma, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":363732,"RR":"<b>Thual, S.; Dewitte, B.</b> (2023). ENSO complexity controlled by zonal shifts in the Walker circulation. <i>Nature Geoscience 16(4)</i>: 328-332. <a href=\"https://dx.doi.org/10.1038/s41561-023-01154-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01154-x</a>","StandardTitle":"ENSO complexity controlled by zonal shifts in the Walker circulation","AuthorsString":"Thual, S.; Dewitte, B.","BibLvlCode":"AS"},{"BRefID":345733,"RR":"<b>Steiger, N.J.; Smerdon, J.E.; Seager, R.; Williams, A.P.; Varuolo-Clarke, A.M.</b> (2021). ENSO-driven coupled megadroughts in North and South America over the last millennium. <i>Nature Geoscience 14(10)</i>: 739-744. <a href=\"https://dx.doi.org/10.1038/s41561-021-00819-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00819-9</a>","StandardTitle":"ENSO-driven coupled megadroughts in North and South America over the last millennium","AuthorsString":"Steiger, N.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":439206,"RR":"<b>Holschuh, N.; Christianson, K.; Dienstfrey, W.; Hills, B.; Hoffman, A.O.; Paden, J.; Winter, K.; Zuraw, R.</b> (2026). Entrained debris records regrowth of the Greenland Ice Sheet after the last interglacial. <i>Nature Geoscience 19(5)</i>: 573-580. <a href=\"https://dx.doi.org/10.1038/s41561-026-01950-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01950-1</a>","StandardTitle":"Entrained debris records regrowth of the Greenland Ice Sheet after the last interglacial","AuthorsString":"Holschuh, N. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":245782,"RR":"<b>Fretwell, P.</b> (2015). Entry beneath ice. <i>Nature Geoscience 8(4)</i>: 253–254. <a href=\"http://dx.doi.org/10.1038/ngeo2396\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2396</a>","StandardTitle":"Entry beneath ice","AuthorsString":"Fretwell, P.","BibLvlCode":"AS"},{"BRefID":356594,"RR":"<b>Claxton, L.M.; McClelland, H.L.O.; Hermoso, M.; Rickaby, R.E.M.</b> (2022). Eocene emergence of highly calcifying coccolithophores despite declining atmospheric CO<sub>2</sub>. <i>Nature Geoscience 15(10)</i>: 826-831. <a href=\"https://dx.doi.org/10.1038/s41561-022-01006-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01006-0</a>","StandardTitle":"Eocene emergence of highly calcifying coccolithophores despite declining atmospheric CO<sub>2</sub>","AuthorsString":"Claxton, L.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":287557,"RR":"<b>Tierney, J.E.; Sinninghe Damsté, J.S.; Pancost, R.D.; Sluijs, A.; Zachos, J.C.</b> (2017). Eocene temperature gradients. <i>Nature Geoscience 10(8)</i>: 538-539. <a href=\"https://dx.doi.org/10.1038/ngeo2997\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2997</a>","StandardTitle":"Eocene temperature gradients","AuthorsString":"Tierney, J.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":344775,"RR":"<b>Lauretano, V.; Kennedy-Asser, A.T.; Korasidis, V.A.; Wallace, M.W.; Valdes, P.J.; Lunt, D.J.; Pancost, R.D.; Naafs, B.D.A.</b> (2021). Eocene to Oligocene terrestrial Southern Hemisphere cooling caused by declining pCO<sub>2</sub>. <i>Nature Geoscience 14(9)</i>: 659-664. <a href=\"https://dx.doi.org/10.1038/s41561-021-00788-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00788-z</a>","StandardTitle":"Eocene to Oligocene terrestrial Southern Hemisphere cooling caused by declining pCO<sub>2</sub>","AuthorsString":"Lauretano, V. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":233940,"RR":"<b>Darby, D.A.</b> (2014). Ephemeral formation of perennial sea ice in the Arctic Ocean during the middle Eocene. <i>Nature Geoscience 7(3)</i>: 210-213. <a href=\"http://dx.doi.org/10.1038/ngeo2068\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2068</a>","StandardTitle":"Ephemeral formation of perennial sea ice in the Arctic Ocean during the middle Eocene","AuthorsString":"Darby, D.A.","BibLvlCode":"AS"},{"BRefID":360453,"RR":"<b>Wan, X.S.; Sheng, H.-X.; Dai, M.; Casciotti, K.L.; Church, M.J.; Zou, W.; Liu, L.; Shen, H.; Zhou, K.; Ward, B.B.; Kao, S.-J.</b> (2023). Epipelagic nitrous oxide production offsets carbon sequestration by the biological pump. <i>Nature Geoscience 16(1)</i>: 29-36. <a href=\"https://dx.doi.org/10.1038/s41561-022-01090-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01090-2</a>","StandardTitle":"Epipelagic nitrous oxide production offsets carbon sequestration by the biological pump","AuthorsString":"Wan, X.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":360454,"RR":"<b>Surawy-Stepney, T.; Hogg, A.E.; Cornford, S.L.; Davison, B.J.</b> (2023). Episodic dynamic change linked to damage on the thwaites glacier ice tongue. <i>Nature Geoscience 16(1)</i>: 37-43. <a href=\"https://dx.doi.org/10.1038/s41561-022-01097-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01097-9</a>","StandardTitle":"Episodic dynamic change linked to damage on the thwaites glacier ice tongue","AuthorsString":"Surawy-Stepney, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":312031,"RR":"<b>Warren-Smith, E.; Fry, B.; Wallace, L.M.; Chon, E.; Henrys, S.; Sheehan, A.F.; Mochizuki, K.; Schwartz, S.Y.; Webb, S.C.; Lebedev, S.</b> (2019). Episodic stress and fluid pressure cycling in subducting oceanic crust during slow slip. <i>Nature Geoscience 12(6)</i>: 475-481. <a href=\"https://dx.doi.org/10.1038/s41561-019-0367-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0367-x</a>","StandardTitle":"Episodic stress and fluid pressure cycling in subducting oceanic crust during slow slip","AuthorsString":"Warren-Smith, E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":436560,"RR":"<b>Jung, Jonathan; Duprey, Nicolas N.; Foreman, Alan D.; D’Olivo, Juan Pablo; Pellio, Carolin; Ryu, Yeongjun; Murphy, Erin L.; Romshoo, Baseerat; Kersting, Diego K.; Cardoso, Gabriel O.; Wald, Tanja; Fripiat, François; Jimenez, Carlos; Gischler, Eberhard; Montagna, Paolo; Alonso-Hernández, Carlos; Gomez-Batista, Miguel; Treinen-Crespo, Christina; Carriquiry, José; Ong, Maria Rosabelle; Goodkin, Nathalie F.; Guppy, Reia; Aardema, Hedy; Slagter, Hans; Heins, Lena; de Angelis, Isabella Hrabe; Bieler, Aaron L.; Yehudai, Maayan; Noël, Trevor P.; James, Kendon; Scholz, Denis; Hu, Chuanmin; Barnes, Brian B.; Pozzer, Andrea; Pöhlker, Christopher; Lelieveld, Jos; Pöschl, Ulrich; Vonhof, Hubert; Haug, Gerald H.; Schiebel, Ralf; Sigman, Daniel M.; Martínez-García, Alfredo</b> (2025). Equatorial upwelling of phosphorus drives Atlantic N<sub>2</sub> fixation and <i>Sargassum</i> blooms. <i>Nature Geoscience 18(12)</i>: 1259-1265. <a href=\"https://dx.doi.org/10.1038/s41561-025-01812-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01812-2</a>","StandardTitle":"Equatorial upwelling of phosphorus drives Atlantic N<sub>2</sub> fixation and <i>Sargassum</i> blooms","AuthorsString":"Jung, Jonathan <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":330719,"RR":"<b>Bjordal, J.; Storelvmo, T.; Alterskjær, K.; Carlsen, T.</b> (2020). Equilibrium climate sensitivity above 5 °C plausible due to state-dependent cloud feedback. <i>Nature Geoscience 13(11)</i>: 718-721. <a href=\"https://dx.doi.org/10.1038/s41561-020-00649-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00649-1</a>","StandardTitle":"Equilibrium climate sensitivity above 5 °C plausible due to state-dependent cloud feedback","AuthorsString":"Bjordal, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":341632,"RR":"<b>Satow, C.; Gudmundsson, A.; Gertisser, R.; Ramsey, C.B.; Bazargan, M.; Pyle, D.M.; Wulf, S.; Miles, A.J.; Hardiman, M.</b> (2021). Eruptive activity of the Santorini Volcano controlled by sea-level rise and fall. <i>Nature Geoscience 14(8)</i>: 586-592. <a href=\"https://dx.doi.org/10.1038/s41561-021-00783-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00783-4</a>","StandardTitle":"Eruptive activity of the Santorini Volcano controlled by sea-level rise and fall","AuthorsString":"Satow, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366127,"RR":"(2023). Estimates of global marine plastic mass demystify the missing plastic paradox. <i>Nature Geoscience 16(8)</i>: 665-666. <a href=\"https://dx.doi.org/10.1038/s41561-023-01220-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01220-4</a>","StandardTitle":"Estimates of global marine plastic mass demystify the missing plastic paradox","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":324018,"RR":"<b>Brendryen, J.; Haflidason, H.; Yokoyama, Y.; Haaga, K.A.; Hannisdal, B.</b> (2020). Eurasian ice sheet collapse was a major source of Meltwater Pulse 1A 14,600 years ago. <i>Nature Geoscience 13(5)</i>: 363-368. <a href=\"https://dx.doi.org/10.1038/s41561-020-0567-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0567-4</a>","StandardTitle":"Eurasian ice sheet collapse was a major source of Meltwater Pulse 1A 14,600 years ago","AuthorsString":"Brendryen, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291301,"RR":"<b>Paulsen, T.; Deering, C.; Sliwinski, J.; Bachmann, O.; Guillong, M.</b> (2017). Evidence for a spike in mantle carbon outgassing during the Ediacaran period. <i>Nature Geoscience 10(12)</i>: 930-934. <a href=\"https://dx.doi.org/10.1038/s41561-017-0011-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0011-6</a>","StandardTitle":"Evidence for a spike in mantle carbon outgassing during the Ediacaran period","AuthorsString":"Paulsen, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396166,"RR":"<b>Normandeau, A.; Eamer, J.B.R.; Way, R.G.; Harrison, E.J.; Cyr, F.; Algar, C.K.; Eamer, J.L.; Geizer, H.D.; Haddock, J.; Kurylyk, B.L.; Van Nieuwenhove, N.; Pijogge, L.; Philibert, G.; Robert, K.; Saunders, M.; Tamborski, J.; Limoges, A.</b> (2024). Evidence for subsea permafrost in subarctic Canada linked to submarine groundwater discharge. <i>Nature Geoscience 17(10)</i>: 1022-1030. <a href=\"https://dx.doi.org/10.1038/s41561-024-01497-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01497-z</a>","StandardTitle":"Evidence for subsea permafrost in subarctic Canada linked to submarine groundwater discharge","AuthorsString":"Normandeau, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":394036,"RR":"<b>Sweetman, A.K.; Smith, A.J.; de Jonge, D.S.W.; Hahn, T.; Schroedl, P.; Silverstein, M.; Andrade, C.; Edwards, R.L.; Lough, A.J.M.; Woulds, C.; Homoky, W.B.; Koschinsky, A.; Fuchs, S.; Kuhn, T.; Geiger, F.; Marlow, J.J.</b> (2024). Evidence of dark oxygen production at the abyssal seafloor. <i>Nature Geoscience 17(8)</i>: 737-739. <a href=\"https://dx.doi.org/10.1038/s41561-024-01480-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01480-8</a>","StandardTitle":"Evidence of dark oxygen production at the abyssal seafloor","AuthorsString":"Sweetman, A.K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":308743,"RR":"<b>Socquet, A.; Hollingsworth, J.; Pathier, E.; Bouchon, M.</b> (2019). Evidence of supershear during the 2018 magnitude 7.5 Palu earthquake from space geodesy. <i>Nature Geoscience 12(3)</i>: 192-199. <a href=\"https://dx.doi.org/10.1038/s41561-018-0296-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0296-0</a>","StandardTitle":"Evidence of supershear during the 2018 magnitude 7.5 Palu earthquake from space geodesy","AuthorsString":"Socquet, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":283786,"RR":"<b>Zhang, G.-L.; Chen, L.-H.; Jackson, M.G.; Hofmann, A.W.</b> (2017). Evolution of carbonated melt to alkali basalt in the South China Sea. <i>Nature Geoscience 10(3)</i>: 229-235. <a href=\"http://dx.doi.org/10.1038/ngeo2877\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2877</a>","StandardTitle":"Evolution of carbonated melt to alkali basalt in the South China Sea","AuthorsString":"Zhang, G.-L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":437136,"RR":"<b>Huang, H.; Gutjahr, M.; Hu, Y.; Pöppelmeier, F.; Kuhn, G.; Lippold, J.; Ronge, T.A.; Wu, S.; Blaser, P.; Lembke-Jene, L.; Jaccard, S.L.; Luo, Y.; Yu, J.</b> (2026). Expansion of Antarctic Bottom Water driven by Antarctic warming in the last deglaciation. <i>Nature Geoscience 19(1)</i>: 113-119. <a href=\"https://dx.doi.org/10.1038/s41561-025-01853-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01853-7</a>","StandardTitle":"Expansion of Antarctic Bottom Water driven by Antarctic warming in the last deglaciation","AuthorsString":"Huang, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291787,"RR":"<b>Hand, K.P.; German, C.R.</b> (2017). Exploring ocean worlds on Earth and beyond. <i>Nature Geoscience 11(1)</i>: 2-4. <a href=\"https://dx.doi.org/10.1038/s41561-017-0045-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0045-9</a>","StandardTitle":"Exploring ocean worlds on Earth and beyond","AuthorsString":"Hand, K.P.; German, C.R.","BibLvlCode":"AS"},{"BRefID":292985,"RR":"<b>Coxall, H.K.; Huck, C.E.; Huber, M.; Lear, C.H.; Legarda-Lisarri, A.; O'Regan, M.; Sliwinska, K.K.; van de Flierdt, T.; de Boer, A.M.; Zachos, J.C.; Backman, J.</b> (2018). Export of nutrient rich northern component water preceded early Oligocene Antarctic glaciation. <i>Nature Geoscience 11(3)</i>: 190-196. <a href=\"https://dx.doi.org/10.1038/s41561-018-0069-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0069-9</a>","StandardTitle":"Export of nutrient rich northern component water preceded early Oligocene Antarctic glaciation","AuthorsString":"Coxall, H.K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":318166,"RR":"<b>McCoy-West, A.J.; Chowdhury, P.; Burton, K.W.; Sossi, P.; Nowell, G.M.; Fitton, J.G.; Kerr, A.C.; Cawood, P.A.; Williams, H.M.</b> (2019). Extensive crustal extraction in Earth’s early history inferred from molybdenum isotopes. <i>Nature Geoscience 12(11)</i>: 946-951. <a href=\"https://dx.doi.org/10.1038/s41561-019-0451-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0451-2</a>","StandardTitle":"Extensive crustal extraction in Earth’s early history inferred from molybdenum isotopes","AuthorsString":"McCoy-West, A.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":230965,"RR":"<b>Bednaršek, N.; Tarling, G.A.; Bakker, D.C.E.; Fielding, S.; Jones, E.M.; Venables, H.J.; Ward, P.; Kuzirian, A.; Lézé, B.; Feely, R.A.; Murphy, E.J.</b> (2012). Extensive dissolution of live pteropods in the Southern Ocean. <i>Nature Geoscience 5(12)</i>: 881-885. <a href=\"http://dx.doi.org/10.1038/NGEO1635\" target=\"_blank\">dx.doi.org/10.1038/NGEO1635</a>","StandardTitle":"Extensive dissolution of live pteropods in the Southern Ocean","AuthorsString":"Bednaršek, N. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":414050,"RR":"<b>Paxman, G.J.G.; Jamieson, S.S.R.; Ross, N.; Bentley, M.J.; Carter, C.M.; Jordan, T.A.; Cui, X.; Lang, S.; Sugden, D.E.; Siegert, M.J.</b> (2025). Extensive fluvial surfaces at the East Antarctic margin have modulated ice-sheet evolution. <i>Nature Geoscience 18(8)</i>: 724-731. <a href=\"https://dx.doi.org/10.1038/s41561-025-01734-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01734-z</a>","StandardTitle":"Extensive fluvial surfaces at the East Antarctic margin have modulated ice-sheet evolution","AuthorsString":"Paxman, G.J.G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":239610,"RR":"<b>Jackson, R.H.; Straneo, F.; Sutherland, D.A.</b> (2014). Externally forced fluctuations in ocean temperature at Greenland glaciers in non-summer months. <i>Nature Geoscience 7(7)</i>: 503 - 508. <a href=\"http://dx.doi.org/10.1038/ngeo2186\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2186</a>","StandardTitle":"Externally forced fluctuations in ocean temperature at Greenland glaciers in non-summer months","AuthorsString":"Jackson, R.H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":320553,"RR":"<b>Saupe, E.E.; Qiao, H.; Donnadieu, Y.; Farnsworth, A.; Kennedy-Asser, A.T.; Ladant, J.-B.; Lunt, D.J.; Pohl, A.; Valdes, P.J.; Finnegan, S.</b> (2020). Extinction intensity during Ordovician and Cenozoic glaciations explained by cooling and palaeogeography. <i>Nature Geoscience 13(1)</i>: 65-70. <a href=\"https://dx.doi.org/10.1038/s41561-019-0504-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0504-6</a>","StandardTitle":"Extinction intensity during Ordovician and Cenozoic glaciations explained by cooling and palaeogeography","AuthorsString":"Saupe, E.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":408005,"RR":"<b>Thirumalai, K.; Clemens, S.C.; Rosenthal, Y.; Condé, S.; Bu, K.; Desprat, S.; Erb, M.; Vetter, L.; Franks, M.; Cheng, J.; Li, L.; Liu, Z.; Zhou, L.P.; Giosan, L.; Singh, A.; Mishra, V.</b> (2025). Extreme Indian summer monsoon states stifled Bay of Bengal productivity across the last deglaciation. <i>Nature Geoscience 18(5)</i>: 443-449. <a href=\"https://dx.doi.org/10.1038/s41561-025-01684-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01684-6</a>","StandardTitle":"Extreme Indian summer monsoon states stifled Bay of Bengal productivity across the last deglaciation","AuthorsString":"Thirumalai, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":260853,"RR":"<b>Maia, M.; Sichel, S.; Briais, A.; Brunelli, D.; Ligi, M.; Ferreira, N.; Campos, T.; Mougel, B.; Brehme, I.; Hémond, C.; Motoki, A.; Moura, D.; Scalabrin, C.; Pessanha, I.; Alves, E.; Ayres, A.; Oliveira, P.</b> (2016). Extreme mantle uplift and exhumation along a transpressive transform fault. <i>Nature Geoscience 9(8)</i>: 619-623. <a href=\"http://dx.doi.org/10.1038/ngeo2759\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2759</a>","StandardTitle":"Extreme mantle uplift and exhumation along a transpressive transform fault","AuthorsString":"Maia, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":283775,"RR":"<b>Waliser, D.; Guan, B.</b> (2017). Extreme winds and precipitation during landfall of atmospheric rivers. <i>Nature Geoscience 10(3)</i>: 179-183. <a href=\"http://dx.doi.org/10.1038/ngeo2894\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2894</a>","StandardTitle":"Extreme winds and precipitation during landfall of atmospheric rivers","AuthorsString":"Waliser, D.; Guan, B.","BibLvlCode":"AS"},{"BRefID":284567,"RR":"<b>Screen, J.A.</b> (2017). Far-flung effects of Arctic warming. <i>Nature Geoscience 10(4)</i>: 253-254. <a href=\"https://dx.doi.org/10.1038/ngeo2924\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2924</a>","StandardTitle":"Far-flung effects of Arctic warming","AuthorsString":"Screen, J.A.","BibLvlCode":"AS"},{"BRefID":392768,"RR":"<b>Hutchins, D.A.; Tagliabue, A.</b> (2024). Feedbacks between phytoplankton and nutrient cycles in a warming ocean. <i>Nature Geoscience 17(6)</i>: 495-502. <a href=\"https://dx.doi.org/10.1038/s41561-024-01454-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01454-w</a>","StandardTitle":"Feedbacks between phytoplankton and nutrient cycles in a warming ocean","AuthorsString":"Hutchins, D.A.; Tagliabue, A.","BibLvlCode":"AS"},{"BRefID":334818,"RR":"<b>Talling, P.J.</b> (2021). Fidelity of turbidites as earthquake records. <i>Nature Geoscience 14(3)</i>: 113-116. <a href=\"https://dx.doi.org/10.1038/s41561-021-00707-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00707-2</a>","StandardTitle":"Fidelity of turbidites as earthquake records","AuthorsString":"Talling, P.J.","BibLvlCode":"AS"},{"BRefID":304299,"RR":"<b>Ding, Q.; Schweiger, A.; L’Heureux, M.; Steig, E.J.; Battisti, D.S.; Johnson, N.C.; Blanchard-Wrigglesworth, E.; Po-Chedley, S.; Zhang, Q.; Harnos, K.; Bushuk, M.; Markle, B.R.; Baxter, I.</b> (2019). Fingerprints of internal drivers of Arctic sea ice loss in observations and model simulations. <i>Nature Geoscience 12(1)</i>: 28-33. <a href=\"https://dx.doi.org/10.1038/s41561-018-0256-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0256-8</a>","StandardTitle":"Fingerprints of internal drivers of Arctic sea ice loss in observations and model simulations","AuthorsString":"Ding, Q. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":260852,"RR":"<b>Ho, S.L.; Laepple, T.</b> (2016). Flat meridional temperature gradient in the early Eocene in the subsurface rather than surface ocean. <i>Nature Geoscience 9(8)</i>: 606-610. <a href=\"http://dx.doi.org/10.1038/ngeo2763\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2763</a>","StandardTitle":"Flat meridional temperature gradient in the early Eocene in the subsurface rather than surface ocean","AuthorsString":"Ho, S.L.; Laepple, T.","BibLvlCode":"AS"},{"BRefID":351958,"RR":"<b>Kasbohm, J.</b> (2022). Flood basalt buildup warms climate. <i>Nature Geoscience 15(5)</i>: 342-343. <a href=\"https://dx.doi.org/10.1038/s41561-022-00944-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00944-z</a>","StandardTitle":"Flood basalt buildup warms climate","AuthorsString":"Kasbohm, J.","BibLvlCode":"AS"},{"BRefID":354969,"RR":"<b>Egbert, G.D.; Yang, B.; Bedrosian, P.A.; Key, K.; Livelybrooks, D.W.; Schultz, A.; Kelbert, A.; Parris, B.</b> (2022). Fluid transport and storage in the Cascadia forearc influenced by overriding plate lithology. <i>Nature Geoscience 15(8)</i>: 677-682. <a href=\"https://dx.doi.org/10.1038/s41561-022-00981-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00981-8</a>","StandardTitle":"Fluid transport and storage in the Cascadia forearc influenced by overriding plate lithology","AuthorsString":"Egbert, G.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":301863,"RR":"<b>Du, J.; Haley, B.A.; Mix, A.C.; Walczak, M.H.; Praetorius, S.K.</b> (2018). Flushing of the deep Pacific Ocean and the deglacial rise of atmospheric CO<sub>2</sub> concentrations. <i>Nature Geoscience 11(10)</i>: 749-755. <a href=\"https://dx.doi.org/10.1038/s41561-018-0205-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0205-6</a>","StandardTitle":"Flushing of the deep Pacific Ocean and the deglacial rise of atmospheric CO<sub>2</sub> concentrations","AuthorsString":"Du, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":347567,"RR":"<b>Repasch, M.; Scheingross, J.S.; Hovius, N.; Lupker, M.; Wittmann, H.; Haghipour, N.; Gröcke, D.R.; Orfeo, O.; Eglinton, T.I.; Sachse, D.</b> (2021). Fluvial organic carbon cycling regulated by sediment transit time and mineral protection. <i>Nature Geoscience 14(11)</i>: 842-848. <a href=\"https://dx.doi.org/10.1038/s41561-021-00845-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00845-7</a>","StandardTitle":"Fluvial organic carbon cycling regulated by sediment transit time and mineral protection","AuthorsString":"Repasch, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359762,"RR":"<b>Meng, X.; Simon, A.C.; Kleinsasser, J.M.; Moles, D.R.; Kontak, D.J.; Jugo, P.J.; Mao, J.; Richards, J.P.</b> (2022). Formation of oxidized sulfur-rich magmas in Neoarchaean subduction zones. <i>Nature Geoscience 15(12)</i>: 1064-1070. <a href=\"https://dx.doi.org/10.1038/s41561-022-01071-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01071-5</a>","StandardTitle":"Formation of oxidized sulfur-rich magmas in Neoarchaean subduction zones","AuthorsString":"Meng, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":287580,"RR":"<b>Egholm, D.L.; Jansen, J.D.; Brædstrup, C.F.; Pedersen, V.K.; Andersen, J.L.; Ugelvig, S.V.; Larsen, N.K.; Knudsen, M.F.</b> (2017). Formation of plateau landscapes on glaciated continental margins. <i>Nature Geoscience 10(8)</i>: 592-597. <a href=\"https://dx.doi.org/10.1038/ngeo2980\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2980</a>","StandardTitle":"Formation of plateau landscapes on glaciated continental margins","AuthorsString":"Egholm, D.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":211516,"RR":"(2011). Forty years of plume research. <i>Nature Geoscience 4(12)</i>: 813. <a href=\"http://dx.doi.org/10.1038/ngeo1348\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1348</a>","StandardTitle":"Forty years of plume research","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":365660,"RR":"<b>Ruben, M.; Hefter, J.; Schubotz, F.; Geibert, W.; Butzin, M.; Gentz, T.; Grotheer, H.; Forwick, M.; Szczucinski, W.; Mollenhauer, G.</b> (2023). Fossil organic carbon utilization in marine Arctic fjord sediments by subsurface micro-organisms. <i>Nature Geoscience 16(7)</i>: 625-630. <a href=\"https://dx.doi.org/10.1038/s41561-023-01198-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01198-z</a>","StandardTitle":"Fossil organic carbon utilization in marine Arctic fjord sediments by subsurface micro-organisms","AuthorsString":"Ruben, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359759,"RR":"<b>Ellerton, D.; Rittenour, T.M.; Shulmeister, J.; Roberts, A.P.; Miot da Silva, G.; Gontz, A.; Hesp, P.A.; Moss, P.; Patton, N.; Santini, T.; Welsh, K.; Zhao, X.</b> (2022). Fraser Island (K'gari) and initiation of the Great Barrier Reef linked by Middle Pleistocene sea-level change. <i>Nature Geoscience 15(12)</i>: 1017-1026. <a href=\"https://dx.doi.org/10.1038/s41561-022-01062-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01062-6</a>","StandardTitle":"Fraser Island (K'gari) and initiation of the Great Barrier Reef linked by Middle Pleistocene sea-level change","AuthorsString":"Ellerton, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":371758,"RR":"<b>Sun, D.; Li, F.; Jing, Z.; Hu, S.; Zhang, B.</b> (2023). Frequent marine heatwaves hidden below the surface of the global ocean. <i>Nature Geoscience 16(12)</i>: 1099-1104. <a href=\"https://dx.doi.org/10.1038/s41561-023-01325-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01325-w</a>","StandardTitle":"Frequent marine heatwaves hidden below the surface of the global ocean","AuthorsString":"Sun, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":242738,"RR":"<b>Reverdin, G.</b> (2014). Freshened from the south. <i>Nature Geoscience 7(11)</i>: 783-784. <a href=\"http://dx.doi.org/10.1038/ngeo2268\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2268</a>","StandardTitle":"Freshened from the south","AuthorsString":"Reverdin, G.","BibLvlCode":"AS"},{"BRefID":308742,"RR":"<b>Ostrander, C.M.; Nielsen, S.G.; Owens, J.D.; Kendall, B.; Gordon, G.W.; Romaniello, S.J.; Anbar, A.D.</b> (2019). Fully oxygenated water columns over continental shelves before the Great Oxidation Event. <i>Nature Geoscience 12(3)</i>: 186-191. <a href=\"https://dx.doi.org/10.1038/s41561-019-0309-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0309-7</a>","StandardTitle":"Fully oxygenated water columns over continental shelves before the Great Oxidation Event","AuthorsString":"Ostrander, C.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":233942,"RR":"<b>Foster, W.J.; Twitchett, R.J.</b> (2014). Functional diversity of marine ecosystems after the Late Permian mass extinction event. <i>Nature Geoscience 7(3)</i>: 233-238. <a href=\"http://dx.doi.org/10.1038/ngeo2079\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2079</a>","StandardTitle":"Functional diversity of marine ecosystems after the Late Permian mass extinction event","AuthorsString":"Foster, W.J.; Twitchett, R.J.","BibLvlCode":"AS"},{"BRefID":142991,"RR":"<b>Ilyina, T.; Zeebe, R.E.; Brewer, P.G.</b> (2010). Future ocean increasingly transparent to low-frequency sound owing to carbon dioxide emissions. <i>Nature Geoscience 3(1)</i>: 18-22. <a href=\"https://dx.doi.org/10.1038/NGEO719\" target=\"_blank\">https://dx.doi.org/10.1038/NGEO719</a>","StandardTitle":"Future ocean increasingly transparent to low-frequency sound owing to carbon dioxide emissions","AuthorsString":"Ilyina, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":330064,"RR":"<b>Lohmann, U.; Friebel, F.; Kanji, Z.A.; Mahrt, F.; Mensah, A.A.; Neubauer, D.</b> (2020). Future warming exacerbated by aged-soot effect on cloud formation. <i>Nature Geoscience 13(10)</i>: 674-680. <a href=\"https://dx.doi.org/10.1038/s41561-020-0631-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0631-0</a>","StandardTitle":"Future warming exacerbated by aged-soot effect on cloud formation","AuthorsString":"Lohmann, U. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":211508,"RR":"<b>Huang, S.; Hall, P.S.; Jackson, M.G.</b> (2011). Geochemical zoning of volcanic chains associated with Pacific hotspots. <i>Nature Geoscience 4(12)</i>: 874-878. <a href=\"http://dx.doi.org/10.1038/ngeo1263\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1263</a>","StandardTitle":"Geochemical zoning of volcanic chains associated with Pacific hotspots","AuthorsString":"Huang, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":245790,"RR":"<b>Cordier, P.</b> (2015). Geodynamics: Strength under pressure. <i>Nature Geoscience 8(4)</i>: 255–256. <a href=\"http://dx.doi.org/10.1038/ngeo2402\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2402</a>","StandardTitle":"Geodynamics: Strength under pressure","AuthorsString":"Cordier, P.","BibLvlCode":"AS"},{"BRefID":439199,"RR":"<b>Iqbal, W.; Frigeri, A.; Asch, K.; Kaskela, A.; Wueller, L.; Rasmussen, M.; Kihlman, S.; Luna, J.; Skinner, J.; Klump, J.; Bernhardt, H.; van der Bogert, C.; Hiesinger, H.; Head, J.</b> (2026). Geological mapping from the ocean floor to outer space. <i>Nature Geoscience 19(5)</i>: 493-495. <a href=\"https://dx.doi.org/10.1038/s41561-026-01968-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01968-5</a>","StandardTitle":"Geological mapping from the ocean floor to outer space","AuthorsString":"Iqbal, W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":354968,"RR":"(2022). Geophysical imaging of fluids in the Cascadia subduction zone. <i>Nature Geoscience 15(8)</i>: 607-608. <a href=\"https://dx.doi.org/10.1038/s41561-022-00984-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00984-5</a>","StandardTitle":"Geophysical imaging of fluids in the Cascadia subduction zone","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":281758,"RR":"<b>de Lavergne, C.; Madec, G.; Capet, X.; Maze, G.; Roquet, F.</b> (2016). Getting to the bottom of the ocean. <i>Nature Geoscience 9(12)</i>: 857-858. <a href=\"http://dx.doi.org/10.1038/ngeo2850\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2850</a>","StandardTitle":"Getting to the bottom of the ocean","AuthorsString":"de Lavergne, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":406640,"RR":"<b>Lucas, N.S.; Brearley, J.A.; Hendry, K.R.; Spira, T.; Braakmann-Folgmann, A.; Abrahamsen, E.P.; Meredith, M.P.; Tarling, G.A.</b> (2025). Giant iceberg meltwater increases upper-ocean stratification and vertical mixing. <i>Nature Geoscience 18(4)</i>: 305-312. <a href=\"https://dx.doi.org/10.1038/s41561-025-01659-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01659-7</a>","StandardTitle":"Giant iceberg meltwater increases upper-ocean stratification and vertical mixing","AuthorsString":"Lucas, N.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":332653,"RR":"<b>Cliff, E.; Khatiwala, S.; Schmittner, A.</b> (2021). Glacial deep ocean deoxygenation driven by biologically mediated air–sea disequilibrium. <i>Nature Geoscience 14(1)</i>: 43-50. <a href=\"https://dx.doi.org/10.1038/s41561-020-00667-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00667-z</a>","StandardTitle":"Glacial deep ocean deoxygenation driven by biologically mediated air–sea disequilibrium","AuthorsString":"Cliff, E.; Khatiwala, S.; Schmittner, A.","BibLvlCode":"AS"},{"BRefID":231284,"RR":"<b>Mohtadi, M.; Oppo, D.W.; Steinke, S.; Stuut, J.B.W.; De Pol-Holz, R.; Hebbeln, D.; Lückge, A.; Stuut, J.B.W.; De-Pol-Holz, R.</b> (2011). Glacial to Holocene swings of the Australian-Indonesian monsoon. <i>Nature Geoscience 4(8)</i>: 540-544. <a href=\"http://dx.doi.org/10.1038/NGEO1209\" target=\"_blank\">dx.doi.org/10.1038/NGEO1209</a>","StandardTitle":"Glacial to Holocene swings of the Australian-Indonesian monsoon","AuthorsString":"Mohtadi, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":243950,"RR":"<b>Hoogakker, B.A.A.; Elderfield, H.; Schmiedl, G.; McCave, I.N.; Rickaby, R.E.M.</b> (2015). Glacial-interglacial changes in bottom-water oxygen content on the Portuguese margin. <i>Nature Geoscience 8(1)</i>: 40–43. <a href=\"http://dx.doi.org/10.1038/ngeo2317\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2317</a>","StandardTitle":"Glacial-interglacial changes in bottom-water oxygen content on the Portuguese margin","AuthorsString":"Hoogakker, B.A.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":309971,"RR":"<b>Tobo, Y.; Adachi, K.; DeMott, P.J.; Hill, T.C.J.; Hamilton, D.S.; Mahowald, N.M.; Nagatsuka, N.; Ohata, S.; Uetake, J.; Kondo, Y.; Koike, M.</b> (2019). Glacially sourced dust as a potentially significant source of ice nucleating particles. <i>Nature Geoscience 12(4)</i>: 253-258. <a href=\"https://dx.doi.org/10.1038/s41561-019-0314-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0314-x</a>","StandardTitle":"Glacially sourced dust as a potentially significant source of ice nucleating particles","AuthorsString":"Tobo, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366130,"RR":"<b>Meire, L.; Paulsen, M.L.; Meire, P.; Rysgaard, S.; Hopwood, M.J.; Sejr, M.K.; Stuart-Lee, A.; Sabbe, K.; Stock, W.; Mortensen, J.</b> (2023). Glacier retreat alters downstream fjord ecosystem structure and function in Greenland. <i>Nature Geoscience 16(8)</i>: 671-674. <a href=\"https://dx.doi.org/10.1038/s41561-023-01218-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01218-y</a>","StandardTitle":"Glacier retreat alters downstream fjord ecosystem structure and function in Greenland","AuthorsString":"Meire, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":123800,"RR":"<b>Ramanathan, V.; Carmichael, G.</b> (2008). Global and regional climate changes due to black carbon. <i>Nature Geoscience 1(4)</i>: 221-227","StandardTitle":"Global and regional climate changes due to black carbon","AuthorsString":"Ramanathan, V.; Carmichael, G.","BibLvlCode":"AS"},{"BRefID":282628,"RR":"<b>Markle, B.R.; Steig, E.J.; Buizert, C.; Schoenemann, S.W.; Bitz, C.M.; Fudge, T.J.; Pedro, J.B.; Ding, Q.; Jones, T.R.; White, J.W.C.; Sowers, T.</b> (2017). Global atmospheric teleconnections during Dansgaard–Oeschger events. <i>Nature Geoscience 10(1)</i>: 36-40. <a href=\"http://dx.doi.org/10.1038/ngeo2848\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2848</a>","StandardTitle":"Global atmospheric teleconnections during Dansgaard–Oeschger events","AuthorsString":"Markle, B.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":337173,"RR":"<b>Gómez-Gener, Lluís; Rocher-Ros, Gerard; Battin, Tom; Cohen, Matthew J.; Dalmagro, Higo J.; Dinsmore, Kerry J.; Drake, Travis W.; Duvert, Clément; Enrich-Prast, Alex; Horgby, Åsa; Johnson, Mark S.; Kirk, Lily; Machado-Silva, Fausto; Marzolf, Nicholas S.; McDowell, Mollie J.; McDowell, William H.; Miettinen, Heli; Ojala, Anne K.; Peter, Hannes; Pumpanen, Jukka; Ran, Lishan; Riveros-Iregui, Diego A.; Santos, Isaac R.; Six, Johan; Stanley, Emily H.; Wallin, Marcus B.; White, Shane A.; Sponseller, Ryan A.</b> (2021). Global carbon dioxide efflux from rivers enhanced by high nocturnal emissions. <i>Nature Geoscience 14(5)</i>: 289-294. <a href=\"https://hdl.handle.net/10.1038/s41561-021-00722-3\" target=\"_blank\">https://hdl.handle.net/10.1038/s41561-021-00722-3</a>","StandardTitle":"Global carbon dioxide efflux from rivers enhanced by high nocturnal emissions","AuthorsString":"Gómez-Gener, Lluís <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":406044,"RR":"<b>Lehmann, N.; Bach, L.T.</b> (2025). Global carbonate chemistry gradients reveal a negative feedback on ocean alkalinity enhancement. <i>Nature Geoscience 18(3)</i>: 232-238. <a href=\"https://dx.doi.org/10.1038/s41561-025-01644-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01644-0</a>","StandardTitle":"Global carbonate chemistry gradients reveal a negative feedback on ocean alkalinity enhancement","AuthorsString":"Lehmann, N.; Bach, L.T.","BibLvlCode":"AS"},{"BRefID":344780,"RR":"<b>Gernon, T.M.; Hincks, T.K.; Merdith, A.S.; Rohling, E.J.; Palmer, M.R.; Foster, G.L.; Bataille, C.P.; Müller, R.D.</b> (2021). Global chemical weathering dominated by continental arcs since the mid-Palaeozoic. <i>Nature Geoscience 14(9)</i>: 690-696. <a href=\"https://dx.doi.org/10.1038/s41561-021-00806-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00806-0</a>","StandardTitle":"Global chemical weathering dominated by continental arcs since the mid-Palaeozoic","AuthorsString":"Gernon, T.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":319471,"RR":"<b>Marzocchi, A.; Jansen, M.F.</b> (2019). Global cooling linked to increased glacial carbon storage via changes in Antarctic sea ice. <i>Nature Geoscience 12(12)</i>: 1001-1005. <a href=\"https://dx.doi.org/10.1038/s41561-019-0466-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0466-8</a>","StandardTitle":"Global cooling linked to increased glacial carbon storage via changes in Antarctic sea ice","AuthorsString":"Marzocchi, A.; Jansen, M.F.","BibLvlCode":"AS"},{"BRefID":296640,"RR":"<b>Egger, M.; Riedinger, N.; Mogollón, J.M.; Jørgensen, B.B.</b> (2018). Global diffusive fluxes of methane in marine sediments. <i>Nature Geoscience 11(6)</i>: 421-425. <a href=\"https://dx.doi.org/10.1038/s41561-018-0122-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0122-8</a>","StandardTitle":"Global diffusive fluxes of methane in marine sediments","AuthorsString":"Egger, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":391796,"RR":"<b>Kohler, T.J.; Bourquin, M.; Peter, H.; Yvon-Durocher, G.; Sinsabaugh, R.L.; Deluigi, N.; Styllas, M.; Schön, M.; Tolosano, M.; de Staercke, V.; Battin, T.J.</b> (2024). Global emergent responses of stream microbial metabolism to glacier shrinkage. <i>Nature Geoscience 17(4)</i>: 309-315. <a href=\"https://dx.doi.org/10.1038/s41561-024-01393-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01393-6</a>","StandardTitle":"Global emergent responses of stream microbial metabolism to glacier shrinkage","AuthorsString":"Kohler, T.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296638,"RR":"<b>Biasutti, M.; Voigt, A.; Boos, W.R.; Braconnot, P.; Hargreaves, J.C.; Harrison, S.P.; Kang, S.M.; Mapes, B.E.; Scheff, J.; Schumacher, C.; Sobel, A.H.; Xie, S.-P.</b> (2018). Global energetics and local physics as drivers of past, present and future monsoons. <i>Nature Geoscience 11(6)</i>: 392-400. <a href=\"https://dx.doi.org/10.1038/s41561-018-0137-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0137-1</a>","StandardTitle":"Global energetics and local physics as drivers of past, present and future monsoons","AuthorsString":"Biasutti, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359504,"RR":"<b>Bao, H.; Xu, L.; Meng, L.; Ampuero, J.-P.; Gao, L.; Zhang, H.</b> (2022). Global frequency of oceanic and continental supershear earthquakes. <i>Nature Geoscience 15(11)</i>: 942-949. <a href=\"https://dx.doi.org/10.1038/s41561-022-01055-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01055-5</a>","StandardTitle":"Global frequency of oceanic and continental supershear earthquakes","AuthorsString":"Bao, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296639,"RR":"<b>Wang, W.; Lee, X.; Liu, S.; Schultz, N.; Wang, Y.; Zhang, M.</b> (2018). Global lake evaporation accelerated by changes in surface energy allocation in a warmer climate. <i>Nature Geoscience 11(6)</i>: 410-414. <a href=\"https://dx.doi.org/10.1038/s41561-018-0114-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0114-8</a>","StandardTitle":"Global lake evaporation accelerated by changes in surface energy allocation in a warmer climate","AuthorsString":"Wang, W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":408334,"RR":"<b>Zhang, Z.; Luo, X.; Friess, D.A.; Li, Y.</b> (2025). Global mangrove growth variability driven by climatic oscillation-induced sea-level fluctuations. <i>Nature Geoscience 18(6)</i>: 488-494. <a href=\"https://dx.doi.org/10.1038/s41561-025-01701-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01701-8</a>","StandardTitle":"Global mangrove growth variability driven by climatic oscillation-induced sea-level fluctuations","AuthorsString":"Zhang, Z. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":349759,"RR":"<b>Hou, X.; Feng, L.; Dai, Y.; Hu, C.; Gibson, L.; Tang, J.; Lee, Z.; Wang, Y.; Cai, X.; Liu, J.; Zheng, Y.; Zheng, C.</b> (2022). Global mapping reveals increase in lacustrine algal blooms over the past decade. <i>Nature Geoscience 15(2)</i>: 130-134. <a href=\"https://dx.doi.org/10.1038/s41561-021-00887-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00887-x</a>","StandardTitle":"Global mapping reveals increase in lacustrine algal blooms over the past decade","AuthorsString":"Hou, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366048,"RR":"<b>Kaandorp, M.L.A.; Lobelle, D.; Kehl, C.; Dijkstra, H.A.; van Sebille, E.</b> (2023). Global mass of buoyant marine plastics dominated by large long-lived debris. <i>Nature Geoscience 16(8)</i>: 689-694. <a href=\"https://dx.doi.org/10.1038/s41561-023-01216-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01216-0</a>","StandardTitle":"Global mass of buoyant marine plastics dominated by large long-lived debris","AuthorsString":"Kaandorp, M.L.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":439198,"RR":"<b>Luo, Q.; Feng, L.; Park, E.; Walling, D.E.; Huang, L.; Wang, M.; Woolway, R.I.; Fang, H.; Gong, J.</b> (2026). Global net increase in surface water connectivity in river–floodplain systems. <i>Nature Geoscience 19(5)</i>: 556-564. <a href=\"https://dx.doi.org/10.1038/s41561-026-01953-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01953-y</a>","StandardTitle":"Global net increase in surface water connectivity in river–floodplain systems","AuthorsString":"Luo, Q. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":294789,"RR":"<b>Bianchi, D.; Weber, T.S.; Kiko, R.; Deutsch, C.</b> (2018). Global niche of marine anaerobic metabolisms expanded by particle microenvironments. <i>Nature Geoscience 11(4)</i>: 263-268. <a href=\"https://dx.doi.org/10.1038/s41561-018-0081-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0081-0</a>","StandardTitle":"Global niche of marine anaerobic metabolisms expanded by particle microenvironments","AuthorsString":"Bianchi, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":395753,"RR":"<b>Parc, L.; Bellenger, H.; Bopp, L.; Perrot, X.; Ho, D.T.</b> (2024). Global ocean carbon uptake enhanced by rainfall. <i>Nature Geoscience 17(9)</i>: 851-857. <a href=\"https://dx.doi.org/10.1038/s41561-024-01517-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01517-y</a>","StandardTitle":"Global ocean carbon uptake enhanced by rainfall","AuthorsString":"Parc, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":320558,"RR":"<b>Shackleton, S.; Baggenstos, D.; Menking, J.A.; Dyonisius, M.N.; Bereiter, B.; Bauska, T.K.; Rhodes, R.H.; Brook, E.J.; Petrenko, V.V.; McConnell, J.R.; Kellerhals, T.; Häberli, M.; Schmitt, J.; Fischer, H.; Severinghaus, J.P.</b> (2020). Global ocean heat content in the Last Interglacial. <i>Nature Geoscience 13(1)</i>: 77-81. <a href=\"https://dx.doi.org/10.1038/s41561-019-0498-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0498-0</a>","StandardTitle":"Global ocean heat content in the Last Interglacial","AuthorsString":"Shackleton, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":310824,"RR":"<b>Forget, G.; Ferreira, D.</b> (2019). Global ocean heat transport dominated by heat export from the tropical Pacific. <i>Nature Geoscience 12(5)</i>: 351-354. <a href=\"https://dx.doi.org/10.1038/s41561-019-0333-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0333-7</a>","StandardTitle":"Global ocean heat transport dominated by heat export from the tropical Pacific","AuthorsString":"Forget, G.; Ferreira, D.","BibLvlCode":"AS"},{"BRefID":359761,"RR":"<b>Inomura, K.; Deutsch, C.; Jahn, O.; Dutkiewicz, S.; Follows, M.J.</b> (2022). Global patterns in marine organic matter stoichiometry driven by phytoplankton ecophysiology. <i>Nature Geoscience 15(12)</i>: 1034-1040. <a href=\"https://dx.doi.org/10.1038/s41561-022-01066-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01066-2</a>","StandardTitle":"Global patterns in marine organic matter stoichiometry driven by phytoplankton ecophysiology","AuthorsString":"Inomura, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392283,"RR":"<b>Collins, E.L.; David, C.H.; Riggs, R.R.; Allen, G.H.; Pavelsky, T.M.; Lin, P.; Pan, M.; Yamazaki, D.; Meentemeyer, R.K.; Sanchez, G.M.</b> (2024). Global patterns in river water storage dependent on residence time. <i>Nature Geoscience 17(5)</i>: 433-439. <a href=\"https://dx.doi.org/10.1038/s41561-024-01421-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01421-5</a>","StandardTitle":"Global patterns in river water storage dependent on residence time","AuthorsString":"Collins, E.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":394037,"RR":"<b>Wang, C.; Qiu, Y.; Hao, Z.; Wang, J.; Zhang, C.; Middelburg, J.J.; Wang, Y.; Zou, X.</b> (2024). Global patterns of organic carbon transfer and accumulation across the land–ocean continuum constrained by radiocarbon data. <i>Nature Geoscience 17(8)</i>: 778-786. <a href=\"https://dx.doi.org/10.1038/s41561-024-01476-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01476-4</a>","StandardTitle":"Global patterns of organic carbon transfer and accumulation across the land–ocean continuum constrained by radiocarbon data","AuthorsString":"Wang, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":321491,"RR":"<b>Flombaum, P.; Wang, W.-L.; Primeau, F.W.; Martiny, A.C.</b> (2020). Global picophytoplankton niche partitioning predicts overall positive response to ocean warming. <i>Nature Geoscience 13(2)</i>: 116-120. <a href=\"https://dx.doi.org/10.1038/s41561-019-0524-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0524-2</a>","StandardTitle":"Global picophytoplankton niche partitioning predicts overall positive response to ocean warming","AuthorsString":"Flombaum, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":395752,"RR":"<b>Liu, Maodian; Raymond, Peter A.; Lauerwald, Ronny; Zhang, Qianru; Trapp-Müller, Gerrit; Davis, Kay L.; Moosdorf, Nils; Xiao, Changhao; Middelburg, Jack J.; Bouwman, Alexander F.; Beusen, Arthur H. W.; Peng, Changhui; Lacroix, Fabrice; Tian, Hanqin; Wang, Junjie; Li, Mingxu; Zhu, Qiuan; Cohen, Sagy; van Hoek, Wim J.; Li, Ya; Li, Yangmingkai; Yao, Yuanzhi; Regnier, Pierre</b> (2024). Global riverine land-to-ocean carbon export constrained by observations and multi-model assessment. <i>Nature Geoscience 17(9)</i>: 896-904. <a href=\"https://dx.doi.org/10.1038/s41561-024-01524-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01524-z</a>","StandardTitle":"Global riverine land-to-ocean carbon export constrained by observations and multi-model assessment","AuthorsString":"Liu, Maodian <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359757,"RR":"<b>Cui, J.; Lian, X.; Huntingford, C.; Gimeno, L.; Wang, T.; Ding, J.; He, M.; Xu, H.; Chen, A.; Gentine, P.; Piao, S.</b> (2022). Global water availability boosted by vegetation-driven changes in atmospheric moisture transport. <i>Nature Geoscience 15(12)</i>: 982-988. <a href=\"https://dx.doi.org/10.1038/s41561-022-01061-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01061-7</a>","StandardTitle":"Global water availability boosted by vegetation-driven changes in atmospheric moisture transport","AuthorsString":"Cui, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":316663,"RR":"<b>Spivak, A.C.; Sanderman, J.; Bowen, J.L.; Canuel, E.A.; Hopkinson, C.S.</b> (2019). Global-change controls on soil-carbon accumulation and loss in coastal vegetated ecosystems. <i>Nature Geoscience 12(9)</i>: 685-692. <a href=\"https://dx.doi.org/10.1038/s41561-019-0435-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0435-2</a>","StandardTitle":"Global-change controls on soil-carbon accumulation and loss in coastal vegetated ecosystems","AuthorsString":"Spivak, A.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":409779,"RR":"<b>Liu, Ji; Wang, Hai; Mou, Juan; Penuelas, Josep; Delgado-Baquerizo, Manuel; Martiny, Adam C.; Zhou, Guiyao; Hutchins, David A.; Inomura, Keisuke; Lomas, Michael W.; Fakhraee, Mojtaba; Pellegrini, Adam; Kohler, Tyler J.; Deutsch, Curtis A.; Planavsky, Noah; Lapointe, Brian; Zhang, Yong; Li, Yanyan; Zhou, Jiacong; Zhang, Yixuan; Sun, Siyi; Li, Yong; Zhang, Wei; Cao, Junji; Chen, Ji</b> (2025). Global-scale shifts in marine ecological stoichiometry over the past 50 years. <i>Nature Geoscience 18(8)</i>: 769-778. <a href=\"https://dx.doi.org/10.1038/s41561-025-01735-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01735-y</a>","StandardTitle":"Global-scale shifts in marine ecological stoichiometry over the past 50 years","AuthorsString":"Liu, Ji <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":243209,"RR":"<b>Teng, Y.-C.; Primeau, F.; Moore, J.K.; Lomas, M.W.; Martiny, A.C.</b> (2014). Global-scale variations of the ratios of carbon to phosphorus in exported marine organic matter. <i>Nature Geoscience 7(12)</i>: 895–898. <a href=\"http://dx.doi.org/10.1038/ngeo2303\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2303</a>","StandardTitle":"Global-scale variations of the ratios of carbon to phosphorus in exported marine organic matter","AuthorsString":"Teng, Y.-C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":368754,"RR":"<b>Konecky, Bronwen L.; McKay, Nicholas P.; Falster, Georgina M.; Stevenson, Samantha L.; Fischer, Matt J.; Atwood, Alyssa R.; Thompson, Diane M.; Jones, Matthew D.; Tyler, Jonathan J.; DeLong, Kristine L.; Martrat, Belen; Thomas, Elizabeth K.; Conroy, Jessica L.; Dee, Sylvia G.; Jonkers, Lukas; Churakova, Olga V.; Kern, Zoltán; Opel, Thomas; Porter, Trevor J.; Sayani, Hussein R.; Skrzypek, Grzegorz; Abram, Nerilie J.; Braun, Kerstin; Carré, Matthieu; Cartapanis, Olivier; Comas-Bru, Laia; Curran, Mark A.; Dassié, Emilie P.; Deininger, Michael; Divine, Dmitry V.; Incarbona, Alessandro; Kaufman, Darrell S.; Kaushal, Nikita; Klaebe, Robert M.; Kolus, Hannah R.; Leduc, Guillaume; Managave, Shreyas R.; Mortyn, P. Graham; Moy, Andrew D.; Orsi, Anais J.; Partin, Judson W.; Roop, Heidi A.; Sicre, Marie-Alexandrine; von Gunten, Lucien; Yoshimura, Kei; Iso2k Project Members</b> (2023). Globally coherent water cycle response to temperature change during the past two millennia. <i>Nature Geoscience 16(11)</i>: 997-1004. <a href=\"https://dx.doi.org/10.1038/s41561-023-01291-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01291-3</a>","StandardTitle":"Globally coherent water cycle response to temperature change during the past two millennia","AuthorsString":"Konecky, Bronwen L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":371746,"RR":"<b>Bond, A.D.; Dickson, A.J.; Ruhl, M.; Bos, R.; van de Schootbrugge, B.</b> (2023). Globally limited but severe shallow-shelf euxinia during the end-Triassic extinction. <i>Nature Geoscience 16(12)</i>: 1181-1187. <a href=\"https://dx.doi.org/10.1038/s41561-023-01303-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01303-2</a>","StandardTitle":"Globally limited but severe shallow-shelf euxinia during the end-Triassic extinction","AuthorsString":"Bond, A.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":252693,"RR":"<b>Naafs, B.D.A.; Castro, J.M.; De Gea, G.A.; Quijano, M.L.; Schmidt, D.N.; Pancost, R.D.</b> (2016). Gradual and sustained carbon dioxide release during Aptian Oceanic Anoxic Event 1a. <i>Nature Geoscience 9(2)</i>: 135-139. <a href=\"http://dx.doi.org/10.1038/ngeo2627\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2627</a>","StandardTitle":"Gradual and sustained carbon dioxide release during Aptian Oceanic Anoxic Event 1a","AuthorsString":"Naafs, B.D.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":353959,"RR":"<b>Ruh, J.B.; Tokle, L.; Behr, W.M.</b> (2022). Grain-size-evolution controls on lithospheric weakening during continental rifting. <i>Nature Geoscience 15(7)</i>: 585-590. <a href=\"https://dx.doi.org/10.1038/s41561-022-00964-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00964-9</a>","StandardTitle":"Grain-size-evolution controls on lithospheric weakening during continental rifting","AuthorsString":"Ruh, J.B.; Tokle, L.; Behr, W.M.","BibLvlCode":"AS"},{"BRefID":338973,"RR":"<b>Cassotto, R.K.; Burton, J.C.; Amundson, J.M.; Fahnestock, M.A.; Truffer, M.</b> (2021). Granular decoherence precedes ice mélange failure and glacier calving at Jakobshavn Isbræ. <i>Nature Geoscience 14(6)</i>: 417-422. <a href=\"https://dx.doi.org/10.1038/s41561-021-00754-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00754-9</a>","StandardTitle":"Granular decoherence precedes ice mélange failure and glacier calving at Jakobshavn Isbræ","AuthorsString":"Cassotto, R.K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":320555,"RR":"<b>Eguchi, J.; Seales, J.; Dasgupta, R.</b> (2020). Great oxidation and Lomagundi events linked by deep cycling and enhanced degassing of carbon. <i>Nature Geoscience 13(1)</i>: 71-76. <a href=\"https://dx.doi.org/10.1038/s41561-019-0492-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0492-6</a>","StandardTitle":"Great oxidation and Lomagundi events linked by deep cycling and enhanced degassing of carbon","AuthorsString":"Eguchi, J.; Seales, J.; Dasgupta, R.","BibLvlCode":"AS"},{"BRefID":348077,"RR":"<b>Sun, C.; Shanahan, T.M.; DiNezio, P.N.; McKay, N.P.; Roy, P.D.</b> (2021). Great Plains storm intensity since the last glacial controlled by spring surface warming. <i>Nature Geoscience 14(12)</i>: 912-917. <a href=\"https://dx.doi.org/10.1038/s41561-021-00860-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00860-8</a>","StandardTitle":"Great Plains storm intensity since the last glacial controlled by spring surface warming","AuthorsString":"Sun, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":294785,"RR":"<b>Walker, R.T.</b> (2018). Grounded meets floating. <i>Nature Geoscience 11(4)</i>: 223-224. <a href=\"https://dx.doi.org/10.1038/s41561-018-0098-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0098-4</a>","StandardTitle":"Grounded meets floating","AuthorsString":"Walker, R.T.","BibLvlCode":"AS"},{"BRefID":365652,"RR":"<b>Kleber, G.E.; Hodson, A.J.; Magerl, L.; Mannerfelt, E.S.; Bradbury, H.J.; Zhu, Y.; Trimmer, M.; Turchyn, A.V.</b> (2023). Groundwater springs formed during glacial retreat are a large source of methane in the high Arctic. <i>Nature Geoscience 16(7)</i>: 597-604. <a href=\"https://dx.doi.org/10.1038/s41561-023-01210-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01210-6</a>","StandardTitle":"Groundwater springs formed during glacial retreat are a large source of methane in the high Arctic","AuthorsString":"Kleber, G.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":364404,"RR":"<b>Kuwahara, H.; Nakada, R.; Kadoya, S.; Yoshino, T.; Irifune, T.</b> (2023). Hadean mantle oxidation inferred from melting of peridotite under lower-mantle conditions. <i>Nature Geoscience 16(5)</i>: 461-465. <a href=\"https://dx.doi.org/10.1038/s41561-023-01169-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01169-4</a>","StandardTitle":"Hadean mantle oxidation inferred from melting of peridotite under lower-mantle conditions","AuthorsString":"Kuwahara, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":336527,"RR":"<b>Rosentreter, J.A.; Borges, A.V.; Deemer, B.R.; Holgerson, M.A.; Liu, S.; Song, C.; Melack, J.; Raymond, P.A.; Duarte, C.M.; Allen, G.H.; Olefeldt, D.; Poulter, B.; Battin, T.I.; Eyre, B.D.</b> (2021). Half of global methane emissions come from highly variable aquatic ecosystem sources. <i>Nature Geoscience 14(4)</i>: 225-230. <a href=\"https://dx.doi.org/10.1038/s41561-021-00715-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00715-2</a>","StandardTitle":"Half of global methane emissions come from highly variable aquatic ecosystem sources","AuthorsString":"Rosentreter, J.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":320532,"RR":"<b>Wyatt, A.S.J.; Leichter, J.J.; Toth, L.T.; Miyajima, T.; Aronson, R.B.; Nagata, T.</b> (2020). Heat accumulation on coral reefs mitigated by internal waves. <i>Nature Geoscience 13(1)</i>: 28-34. <a href=\"https://dx.doi.org/10.1038/s41561-019-0486-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0486-4</a>","StandardTitle":"Heat accumulation on coral reefs mitigated by internal waves","AuthorsString":"Wyatt, A.S.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":336524,"RR":"<b>Allard, J.L.; Hughes, P.D.; Woodward, J.C.</b> (2021). Heinrich Stadial aridity forced Mediterranean-wide glacier retreat in the last cold stage. <i>Nature Geoscience 14(4)</i>: 197-205. <a href=\"https://dx.doi.org/10.1038/s41561-021-00703-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00703-6</a>","StandardTitle":"Heinrich Stadial aridity forced Mediterranean-wide glacier retreat in the last cold stage","AuthorsString":"Allard, J.L.; Hughes, P.D.; Woodward, J.C.","BibLvlCode":"AS"},{"BRefID":287575,"RR":"<b>Chung, E-S.; Soden, B.J.</b> (2017). Hemispheric climate shifts driven by anthropogenic aerosol–cloud interactions. <i>Nature Geoscience 10(8)</i>: 566-571. <a href=\"https://dx.doi.org/10.1038/ngeo2988\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2988</a>","StandardTitle":"Hemispheric climate shifts driven by anthropogenic aerosol–cloud interactions","AuthorsString":"Chung, E-S.; Soden, B.J.","BibLvlCode":"AS"},{"BRefID":247386,"RR":"<b>Vialard, J.</b> (2015). Hiatus heat in the Indian Ocean. <i>Nature Geoscience 8(6)</i>: 423–424. <a href=\"http://dx.doi.org/10.1038/ngeo2442\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2442</a>","StandardTitle":"Hiatus heat in the Indian Ocean","AuthorsString":"Vialard, J.","BibLvlCode":"AS"},{"BRefID":359508,"RR":"(2022). Hidden rivers under Antarctica impact ice flow and stability. <i>Nature Geoscience 15(11)</i>: 869-870. <a href=\"https://dx.doi.org/10.1038/s41561-022-01060-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01060-8</a>","StandardTitle":"Hidden rivers under Antarctica impact ice flow and stability","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":258272,"RR":"<b>González-Gaya, B.; Fernández-Pinos, M.-C.; Morales, L.; Méjanelle, L.; Abad, E.; Piña, B.; Duarte, C.M.; Jiménez, B.; Dachs, J.</b> (2016). High atmosphere–ocean exchange of semivolatile aromatic hydrocarbons. <i>Nature Geoscience 9(6)</i>: 438-442. <a href=\"http://dx.doi.org/10.1038/ngeo2714\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2714</a>","StandardTitle":"High atmosphere–ocean exchange of semivolatile aromatic hydrocarbons","AuthorsString":"González-Gaya, B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":238940,"RR":"<b>Garcia-Serrano, J.; Frankignoul, C.</b> (2014). High predictability of the winter Euro–Atlantic climate from cryospheric variability. <i>Nature Geoscience 7(E2)</i>: 1-5. <a href=\"http://dx.doi.org/10.1038/ngeo2164\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2164</a>","StandardTitle":"High predictability of the winter Euro–Atlantic climate from cryospheric variability","AuthorsString":"Garcia-Serrano, J.; Frankignoul, C.","BibLvlCode":"AS"},{"BRefID":247380,"RR":"<b>Smith, R.W.; Bianchi, T.S.; Allison, M.; Savage, C.; Galy, V.</b> (2015). High rates of organic carbon burial in fjord sediments globally. <i>Nature Geoscience 8(6)</i>: 450–453. <a href=\"http://dx.doi.org/10.1038/ngeo2421\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2421</a>","StandardTitle":"High rates of organic carbon burial in fjord sediments globally","AuthorsString":"Smith, R.W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359514,"RR":"<b>Hage, S.; Romans, B.W.; Peploe, T.G.E.; Poyatos-Moré, M.; Haeri Ardakani, O.; Bell, D.; Englert, R.G.; Kaempfe-Droguett, S.A.; Nesbit, P.R.; Sherstan, G.; Synnott, D.P.; Hubbard, S.M.</b> (2022). High rates of organic carbon burial in submarine deltas maintained on geological timescales. <i>Nature Geoscience 15(11)</i>: 919-924. <a href=\"https://dx.doi.org/10.1038/s41561-022-01048-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01048-4</a>","StandardTitle":"High rates of organic carbon burial in submarine deltas maintained on geological timescales","AuthorsString":"Hage, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":123798,"RR":"<b>Rohling, E.J.; Grant, K.; Hemleben, Ch.; Siddall, M.; Hoogakker, B.A.A.; Bolshaw, M.; Kucera, M.</b> (2008). High rates of sea-level rise during the last interglacial period. <i>Nature Geoscience 1(1)</i>: 38-42","StandardTitle":"High rates of sea-level rise during the last interglacial period","AuthorsString":"Rohling, E.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":240071,"RR":"<b>O'Brien, C.L.; Foster, G.L.; Martínez-Boti, M.A.; Abell, R.; Rae, J.W.B.</b> (2014). High sea surface temperatures in tropical warm pools during the Pliocene. <i>Nature Geoscience 7(8)</i>: 606-611. <a href=\"http://dx.doi.org/10.1038/ngeo2194\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2194</a>","StandardTitle":"High sea surface temperatures in tropical warm pools during the Pliocene","AuthorsString":"O'Brien, C.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":301866,"RR":"<b>Naafs, B.D.A.; Rohrssen, M.; Inglis, G.N.; Lähteenoja, O.; Feakins, S.J.; Collinson, M.E.; Kennedy, E.M.; Singh, P.K.; Singh, M.P.; Lunt, D.J.; Pancost, R.D.</b> (2018). High temperatures in the terrestrial mid-latitudes during the early Palaeogene. <i>Nature Geoscience 11(10)</i>: 766-771. <a href=\"https://dx.doi.org/10.1038/s41561-018-0199-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0199-0</a>","StandardTitle":"High temperatures in the terrestrial mid-latitudes during the early Palaeogene","AuthorsString":"Naafs, B.D.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366744,"RR":"<b>Ibarra, D.E.; Dai, J.; Gao, Y.; Lang, X.; Duan, P.; Gao, Z.; Chen, J.; Methner, K.; Sha, L.; Tong, H.; Han, X.; Zhu, D.; Li, Y.; Tang, J.; Cheng, H.; Chamberlain, C.P.; Wang, C.</b> (2023). High-elevation Tibetan Plateau before India–Eurasia collision recorded by triple oxygen isotopes. <i>Nature Geoscience 16(9)</i>: 810-815. <a href=\"https://dx.doi.org/10.1038/s41561-023-01243-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01243-x</a>","StandardTitle":"High-elevation Tibetan Plateau before India–Eurasia collision recorded by triple oxygen isotopes","AuthorsString":"Ibarra, D.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":312026,"RR":"<b>Freund, M.B.; Henley, B.J.; Karoly, D.; McGregor, H.V.; Abram, N.J.; Dommenget, D.</b> (2019). Higher frequency of Central Pacific El Niño events in recent decades relative to past centuries. <i>Nature Geoscience 12(6)</i>: 450-455. <a href=\"https://dx.doi.org/10.1038/s41561-019-0353-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0353-3</a>","StandardTitle":"Higher frequency of Central Pacific El Niño events in recent decades relative to past centuries","AuthorsString":"Freund, M.B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":406641,"RR":"<b>Kim, H.; Kang, S.M.; Pendergrass, A.G.; Lehner, F.; Shin, Y.; Ceppi, P.; Yeh, S.-W.; Song, S.-Y.</b> (2025). Higher precipitation in East Asia and western United States expected with future Southern Ocean warming. <i>Nature Geoscience 18(4)</i>: 313-321. <a href=\"https://dx.doi.org/10.1038/s41561-025-01669-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01669-5</a>","StandardTitle":"Higher precipitation in East Asia and western United States expected with future Southern Ocean warming","AuthorsString":"Kim, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":312032,"RR":"<b>Lambart, S.; Koornneef, J.M.; Millet, M.-A.; Davies, G.R.; Cook, M.; Lissenberg, C.J.</b> (2019). Highly heterogeneous depleted mantle recorded in the lower oceanic crust. <i>Nature Geoscience 12(6)</i>: 482-486. <a href=\"https://dx.doi.org/10.1038/s41561-019-0368-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0368-9</a>","StandardTitle":"Highly heterogeneous depleted mantle recorded in the lower oceanic crust","AuthorsString":"Lambart, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":394038,"RR":"<b>Bailey, L.P.; Clare, M.A.; Hunt, J.E.; Kane, I.A.; Miramontes, E.; Fonnesu, M.; Argiolas, R.; Malgesini, G.; Wallerand, R.</b> (2024). Highly variable deep-sea currents over tidal and seasonal timescales. <i>Nature Geoscience 17(8)</i>: 787-794. <a href=\"https://dx.doi.org/10.1038/s41561-024-01494-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01494-2</a>","StandardTitle":"Highly variable deep-sea currents over tidal and seasonal timescales","AuthorsString":"Bailey, L.P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":365654,"RR":"<b>Hudson, T.S.; Kufner, S.K.; Brisbourne, A.M.; Kendall, J.M.; Smith, A.M.; Alley, R.B.; Arthern, R.J.; Murray, T.</b> (2023). Highly variable friction and slip observed at Antarctic ice stream bed. <i>Nature Geoscience 16(7)</i>: 612-618. <a href=\"https://dx.doi.org/10.1038/s41561-023-01204-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01204-4</a>","StandardTitle":"Highly variable friction and slip observed at Antarctic ice stream bed","AuthorsString":"Hudson, T.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":247382,"RR":"<b>Keil, R.</b> (2015). Hoard of fjord carbon. <i>Nature Geoscience 8(6)</i>: 426 -427. <a href=\"http://dx.doi.org/10.1038/ngeo2433\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2433</a>","StandardTitle":"Hoard of fjord carbon","AuthorsString":"Keil, R.","BibLvlCode":"AS"},{"BRefID":311520,"RR":"<b>Saunders, K.M.; Roberts, S.J.; Perren, B.; Butz, C.; Sime, L.; Davies, S.; Van Nieuwenhuyze, W.; Grosjean, M.; Hodgson, D.A.</b> (2018). Holocene dynamics of the Southern Hemisphere westerly winds and possible links to CO<sub>2</sub> outgassing. <i>Nature Geoscience 11(9)</i>: 650-655. <a href=\"https://dx.doi.org/10.1038/s41561-018-0186-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0186-5</a>","StandardTitle":"Holocene dynamics of the Southern Hemisphere westerly winds and possible links to CO<sub>2</sub> outgassing","AuthorsString":"Saunders, K.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359758,"RR":"<b>Franke, S.; Bons, P.D.; Westhoff, J.; Weikusat, I.; Binder, T.; Streng, K.; Steinhage, D.; Helm, V.; Eisen, O.; Paden, J.D.; Eagles, G.; Jansen, D.</b> (2022). Holocene ice-stream shutdown and drainage basin reconfiguration in northeast Greenland. <i>Nature Geoscience 15(12)</i>: 995-1001. <a href=\"https://dx.doi.org/10.1038/s41561-022-01082-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01082-2</a>","StandardTitle":"Holocene ice-stream shutdown and drainage basin reconfiguration in northeast Greenland","AuthorsString":"Franke, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":285915,"RR":"<b>Baker, J.L.; Lachniet, M.S.; Chervyatsova, O.; Asmerom, Y.; Polyak, V.J.</b> (2017). Holocene warming in western continental Eurasia driven by glacial retreat and greenhouse forcing. <i>Nature Geoscience 10(6)</i>: 430-435. <a href=\"https://dx.doi.org/10.1038/ngeo2953\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2953</a>","StandardTitle":"Holocene warming in western continental Eurasia driven by glacial retreat and greenhouse forcing","AuthorsString":"Baker, J.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":408328,"RR":"(2025). Huge submarine eruptions impact global climate but produce low atmospheric sulfur outputs. <i>Nature Geoscience 18(6)</i>: 455-456. <a href=\"https://dx.doi.org/10.1038/s41561-025-01692-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01692-6</a>","StandardTitle":"Huge submarine eruptions impact global climate but produce low atmospheric sulfur outputs","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":312361,"RR":"<b>Abbott, B.W.; Bishop, K.; Zarnetske, J.P.; Minaudo, C.; Chapin III, F.S.; Krause, S.; Hannah, D.M.; Conner, L.; Ellison, D.; Godsey, S.E.; Plont, S.; Marçais, J.; Kolbe, T.; Huebner, A.; Frei, R.J.; Hampton, T.; Gu, S.; Buhman, M.; Sara Sayedi, S.; Ursache, O.; Chapin, M.; Henderson, K.D.; Pinay, G.</b> (2019). Human domination of the global water cycle absent from depictions and perceptions. <i>Nature Geoscience 12(7)</i>: 533-540. <a href=\"https://dx.doi.org/10.1038/s41561-019-0374-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0374-y</a>","StandardTitle":"Human domination of the global water cycle absent from depictions and perceptions","AuthorsString":"Abbott, B.W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":406639,"RR":"<b>Lamb, S.</b> (2025). Humans move water and mantle. <i>Nature Geoscience 18(4)</i>: 277-278. <a href=\"https://dx.doi.org/10.1038/s41561-025-01665-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01665-9</a>","StandardTitle":"Humans move water and mantle","AuthorsString":"Lamb, S.","BibLvlCode":"AS"},{"BRefID":231014,"RR":"<b>Richoz, S.; van de Schootbrugge, B.; Pross, J.; Püttmann, W.; Quan, T.M.; Lindström, S.; Heunisch, C.; Fiebig, J.; Maquil, R.; Schouten, S.; Hauzenberger, C.A.; Wignall, P.B.</b> (2012). Hydrogen sulphide poisoning of shallow seas following the end-Triassic extinction. <i>Nature Geoscience 5(9)</i>: 662-667. <a href=\"http://dx.doi.org/10.1038/NGEO1539\" target=\"_blank\">dx.doi.org/10.1038/NGEO1539</a>","StandardTitle":"Hydrogen sulphide poisoning of shallow seas following the end-Triassic extinction","AuthorsString":"Richoz, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":312363,"RR":"<b>Robbins, L.J.; Funk, S.P.; Flynn, S.L.; Warchola, T.J.; Li, Z.; Lalonde, S.V.; Rostron, B.J.; Smith, A.J.B.; Beukes, N.J.; de Kock, M.O.; Heaman, L.M.; Alessi, D.S.; Konhauser, K.O.</b> (2019). Hydrogeological constraints on the formation of Palaeoproterozoic banded iron formations. <i>Nature Geoscience 12(7)</i>: 558-563. <a href=\"https://dx.doi.org/10.1038/s41561-019-0372-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0372-0</a>","StandardTitle":"Hydrogeological constraints on the formation of Palaeoproterozoic banded iron formations","AuthorsString":"Robbins, L.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":338979,"RR":"<b>Bradshaw, C.D.; Langebroek, P.M.; Lear, C.H.; Lunt, D.J.; Coxall, H.K.; Sosdian, S.M.; de Boer, A.M.</b> (2021). Hydrological impact of Middle Miocene Antarctic ice-free areas coupled to deep ocean temperatures. <i>Nature Geoscience 14(6)</i>: 429-436. <a href=\"https://dx.doi.org/10.1038/s41561-021-00745-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00745-w</a>","StandardTitle":"Hydrological impact of Middle Miocene Antarctic ice-free areas coupled to deep ocean temperatures","AuthorsString":"Bradshaw, C.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392771,"RR":"<b>Jian, H.; Canales, J.P.; Dunn, R.R.; Nedimovic, M.R.</b> (2024). Hydrothermal flow and serpentinization in oceanic core complexes controlled by mafic intrusions. <i>Nature Geoscience 17(6)</i>: 566-571. <a href=\"https://dx.doi.org/10.1038/s41561-024-01444-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01444-y</a>","StandardTitle":"Hydrothermal flow and serpentinization in oceanic core complexes controlled by mafic intrusions","AuthorsString":"Jian, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291788,"RR":"<b>Lang, S.Q.</b> (2018). Hydrothermal stamp on the oceans. <i>Nature Geoscience 11(1)</i>: 10-12. <a href=\"https://dx.doi.org/10.1038/s41561-017-0044-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0044-x</a>","StandardTitle":"Hydrothermal stamp on the oceans","AuthorsString":"Lang, S.Q.","BibLvlCode":"AS"},{"BRefID":349758,"RR":"<b>Millan, R.; Mouginot, J.; Rabatel, A.; Morlighem, M.</b> (2022). Ice velocity and thickness of the world’s glaciers. <i>Nature Geoscience 15(2)</i>: 124-129. <a href=\"https://dx.doi.org/10.1038/s41561-021-00885-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00885-z</a>","StandardTitle":"Ice velocity and thickness of the world’s glaciers","AuthorsString":"Millan, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":352881,"RR":"<b>Braun, C.; Hörner, J.; Voigt, A.; Pinto, J.G.</b> (2022). Ice-free tropical waterbelt for Snowball Earth events questioned by uncertain clouds. <i>Nature Geoscience 15(6)</i>: 489-493. <a href=\"https://dx.doi.org/10.1038/s41561-022-00950-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00950-1</a>","StandardTitle":"Ice-free tropical waterbelt for Snowball Earth events questioned by uncertain clouds","AuthorsString":"Braun, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":302859,"RR":"<b>Bhattacharya, T.; Tierney, J.; Addison, J.A.; Murray, J.W.</b> (2018). Ice-sheet modulation of deglacial North American monsoon intensification. <i>Nature Geoscience 11(11)</i>: 848-852. <a href=\"https://dx.doi.org/10.1038/s41561-018-0220-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0220-7</a>","StandardTitle":"Ice-sheet modulation of deglacial North American monsoon intensification","AuthorsString":"Bhattacharya, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":404830,"RR":"<b>Alley, K.E.</b> (2024). Ice-shelf disintegration in East Antarctica. <i>Nature Geoscience 17(12)</i>: 1193-1194. <a href=\"https://dx.doi.org/10.1038/s41561-024-01607-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01607-x</a>","StandardTitle":"Ice-shelf disintegration in East Antarctica","AuthorsString":"Alley, K.E.","BibLvlCode":"AS"},{"BRefID":365653,"RR":"(2023). Icequakes used to measure friction and slip at a glacier bed. <i>Nature Geoscience 16(7)</i>: 556-557. <a href=\"https://dx.doi.org/10.1038/s41561-023-01207-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01207-1</a>","StandardTitle":"Icequakes used to measure friction and slip at a glacier bed","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":302783,"RR":"<b>Metcalfe, S.E.</b> (2018). Icy grip on glacial monsoon. <i>Nature Geoscience 11(11)</i>: 802-803. <a href=\"https://dx.doi.org/10.1038/s41561-018-0231-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0231-4</a>","StandardTitle":"Icy grip on glacial monsoon","AuthorsString":"Metcalfe, S.E.","BibLvlCode":"AS"},{"BRefID":281764,"RR":"<b>Zhou, C.; Zelinka, M.D.; Klein, S.A.</b> (2016). Impact of decadal cloud variations on the Earth’s energy budget. <i>Nature Geoscience 9(12)</i>: 871-874. <a href=\"http://dx.doi.org/10.1038/ngeo2828\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2828</a>","StandardTitle":"Impact of decadal cloud variations on the Earth’s energy budget","AuthorsString":"Zhou, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":289771,"RR":"<b>Neill, C.; Marchi, S.; Zhang, S.; Bottke, W.</b> (2017). Impact-driven subduction on the Hadean Earth. <i>Nature Geoscience 10(10)</i>: 793-797. <a href=\"https://dx.doi.org/10.1038/ngeo3029\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3029</a>","StandardTitle":"Impact-driven subduction on the Hadean Earth","AuthorsString":"Neill, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":324980,"RR":"<b>Gartman, A.; Findlay, A.J.</b> (2020). Impacts of hydrothermal plume processes on oceanic metal cycles and transport. <i>Nature Geoscience 13(6)</i>: 396-402. <a href=\"https://dx.doi.org/10.1038/s41561-020-0579-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0579-0</a>","StandardTitle":"Impacts of hydrothermal plume processes on oceanic metal cycles and transport","AuthorsString":"Gartman, A.; Findlay, A.J.","BibLvlCode":"AS"},{"BRefID":438827,"RR":"<b>He, G.; Lu, M.; Yang, Y.; Zhang, Q.; Liu, W.; Rillig, M.C.</b> (2026). Impacts of microplastics on terrestrial soil carbon dynamics. <i>Nature Geoscience 19(4)</i>: 384-389. <a href=\"https://dx.doi.org/10.1038/s41561-026-01935-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01935-0</a>","StandardTitle":"Impacts of microplastics on terrestrial soil carbon dynamics","AuthorsString":"He, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":254716,"RR":"<b>Alley, K.E.; Scambos, T.A.; Siegfried, M.R.; Fricker, H.A.</b> (2016). Impacts of warm water on Antarctic ice shelf stability through basal channel formation. <i>Nature Geoscience 9(4)</i>: 290-293. <a href=\"http://dx.doi.org/10.1038/ngeo2675\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2675</a>","StandardTitle":"Impacts of warm water on Antarctic ice shelf stability through basal channel formation","AuthorsString":"Alley, K.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":336528,"RR":"<b>Kranzler, C.F.; Brzezinski, M.A.; Cohen, N.R.; Lampe, R.H.; Maniscalco, M.; Till, C.P.; Mack, J.; Latham, J.R.; Bruland, K.W.; Twining, B.S.; Marchetti, A.; Thamatrakoln, K.</b> (2021). Impaired viral infection and reduced mortality of diatoms in iron-limited oceanic regions. <i>Nature Geoscience 14(4)</i>: 231-237. <a href=\"https://dx.doi.org/10.1038/s41561-021-00711-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00711-6</a>","StandardTitle":"Impaired viral infection and reduced mortality of diatoms in iron-limited oceanic regions","AuthorsString":"Kranzler, C.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":320540,"RR":"<b>Bronselaer, B.; Russell, J.L.; Winton, M.; Williams, N.L.; Key, R.M.; Dunne, J.P.; Feely, R.A.; Johnson, K.S.; Sarmiento, J.L.</b> (2020). Importance of wind and meltwater for observed chemical and physical changes in the Southern Ocean. <i>Nature Geoscience 13(1)</i>: 35-42. <a href=\"https://dx.doi.org/10.1038/s41561-019-0502-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0502-8</a>","StandardTitle":"Importance of wind and meltwater for observed chemical and physical changes in the Southern Ocean","AuthorsString":"Bronselaer, B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":316665,"RR":"<b>Ortega, A.; Geraldi, N.R.; Alam, I.; Kamau, A.A.; Acinas, S.G.; Logares, R.; Gasol, J.M.; Krause-Jensen, D.; Duarte, C.M.</b> (2019). Important contribution of macroalgae to oceanic carbon sequestration. <i>Nature Geoscience 12(9)</i>: 748–754. <a href=\"https://dx.doi.org/10.1038/s41561-019-0421-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0421-8</a>","StandardTitle":"Important contribution of macroalgae to oceanic carbon sequestration","AuthorsString":"Ortega, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":243205,"RR":"<b>Sverjensky, D.A.; Stagno, V.; Huang, F.</b> (2014). Important role for organic carbon in subduction-zone fluids in the deep carbon cycle. <i>Nature Geoscience 7(12)</i>: 909–913. <a href=\"http://dx.doi.org/10.1038/ngeo2291\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2291</a>","StandardTitle":"Important role for organic carbon in subduction-zone fluids in the deep carbon cycle","AuthorsString":"Sverjensky, D.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":298394,"RR":"<b>Shen, J.; Pearson, A.; Henkes, G.A.; Zhang, Y.G.; Chen, K.; Li, D.; Wankel, S.D.; Finney, S.C.; Shen, Y.</b> (2018). Improved efficiency of the biological pump as a trigger for the Late Ordovician glaciation. <i>Nature Geoscience 11(7)</i>: 510-514. <a href=\"https://dx.doi.org/10.1038/s41561-018-0141-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0141-5</a>","StandardTitle":"Improved efficiency of the biological pump as a trigger for the Late Ordovician glaciation","AuthorsString":"Shen, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":249209,"RR":"<b>Tilling, R.L.; Ridout, A.; Shepherd, A.; Wingham, D.J.</b> (2015). Increased Arctic sea ice volume after anomalously low melting in 2013. <i>Nature Geoscience 8(8)</i>: 643-646. <a href=\"http://dx.doi.org/10.1038/ngeo2489\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2489</a>","StandardTitle":"Increased Arctic sea ice volume after anomalously low melting in 2013","AuthorsString":"Tilling, R.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":405770,"RR":"<b>Chudley, T.R.; Howat, I.M.; King, M.D.; MacKie, E.J.</b> (2025). Increased crevassing across accelerating Greenland Ice Sheet margins. <i>Nature Geoscience 18(2)</i>: 148-153. <a href=\"https://dx.doi.org/10.1038/s41561-024-01636-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01636-6</a>","StandardTitle":"Increased crevassing across accelerating Greenland Ice Sheet margins","AuthorsString":"Chudley, T.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":406642,"RR":"<b>Lu, Z.; Schultze, A.; Carré, M.; Brierley, C.; Hopcroft, P.O.; Zhao, D.; Zheng, M.; Braconnot, P.; Yin, Q.; Jungclaus, J.H.; Shi, X.; Yang, H.; Zhang, Q.</b> (2025). Increased frequency of multi-year El Niño–Southern Oscillation events across the Holocene. <i>Nature Geoscience 18(4)</i>: 337-343. <a href=\"https://dx.doi.org/10.1038/s41561-025-01670-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01670-y</a>","StandardTitle":"Increased frequency of multi-year El Niño–Southern Oscillation events across the Holocene","AuthorsString":"Lu, Z. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":351417,"RR":"<b>Yamamoto, M.; Clemens, S.C.; Seki, O.; Tsuchiya, Y.; Huang, Y.; O’ishi, R.; Abe-Ouchi, A.</b> (2022). Increased interglacial atmospheric CO<sub>2</sub> levels followed the mid-Pleistocene Transition. <i>Nature Geoscience 15(4)</i>: 307-313. <a href=\"https://dx.doi.org/10.1038/s41561-022-00918-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00918-1</a>","StandardTitle":"Increased interglacial atmospheric CO<sub>2</sub> levels followed the mid-Pleistocene Transition","AuthorsString":"Yamamoto, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":301864,"RR":"<b>Studer, A.S.; Sigman, D.M.; Martínez-Garcia, A.; Thöle, L.M.; Michel, E.; Jaccard, S.L.; Lippold, J.A.; Mazaud, A.; Wang, X.T.; Robinson, L.F.; Adkins, J.F.; Haug, G.H.</b> (2018). Increased nutrient supply to the Southern Ocean during the Holocene and its implications for the pre-industrial atmospheric CO<sub>2</sub> rise. <i>Nature Geoscience 11(10)</i>: 756-760. <a href=\"https://dx.doi.org/10.1038/s41561-018-0191-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0191-8</a>","StandardTitle":"Increased nutrient supply to the Southern Ocean during the Holocene and its implications for the pre-industrial atmospheric CO<sub>2</sub> rise","AuthorsString":"Studer, A.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":333777,"RR":"<b>Stuart-Smith, R.F.; Roe, G.H.; Li, S.; Allen, M.R.</b> (2021). Increased outburst flood hazard from Lake Palcacocha due to human-induced glacier retreat. <i>Nature Geoscience 14(2)</i>: 85-90. <a href=\"https://dx.doi.org/10.1038/s41561-021-00686-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00686-4</a>","StandardTitle":"Increased outburst flood hazard from Lake Palcacocha due to human-induced glacier retreat","AuthorsString":"Stuart-Smith, R.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":365657,"RR":"<b>Chen, W.-H.; Ren, H.; Chiang, J.C.H.; Wang, Y.-L.; Cai-Li, R.-Y.; Chen, Y.-C.; Shen, C.-C.; Taylor, F.W.; DeCarlo, T.M.; Wu, C.-R.; Mii, H.-S.; Wang, X.T.</b> (2023). Increased tropical South Pacific western boundary current transport over the past century. <i>Nature Geoscience 16(7)</i>: 590-596. <a href=\"https://dx.doi.org/10.1038/s41561-023-01212-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01212-4</a>","StandardTitle":"Increased tropical South Pacific western boundary current transport over the past century","AuthorsString":"Chen, W.-H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":331729,"RR":"<b>Bramante, J.F.; Ford, M.R.; Kench, P.S.; Ashton, A.D.; Toomey, M.R.; Sullivan, R.M.; Karnauskas, K.B.; Ummenhofer, C.C.; Donnelly, J.P.</b> (2020). Increased typhoon activity in the Pacific deep tropics driven by Little Ice Age circulation changes. <i>Nature Geoscience 13(12)</i>: 806-811. <a href=\"https://dx.doi.org/10.1038/s41561-020-00656-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00656-2</a>","StandardTitle":"Increased typhoon activity in the Pacific deep tropics driven by Little Ice Age circulation changes","AuthorsString":"Bramante, J.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":363736,"RR":"<b>Tapu, A.T.; Ubide, T.; Vasconcelos, P.M.</b> (2023). Increasing complexity in magmatic architecture of volcanoes along a waning hotspot. <i>Nature Geoscience 16(4)</i>: 371-379. <a href=\"https://dx.doi.org/10.1038/s41561-023-01156-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01156-9</a>","StandardTitle":"Increasing complexity in magmatic architecture of volcanoes along a waning hotspot","AuthorsString":"Tapu, A.T.; Ubide, T.; Vasconcelos, P.M.","BibLvlCode":"AS"},{"BRefID":439205,"RR":"<b>Tian, S.; Li, D.; Zhang, T.; McClelland, J.W.; Overeem, I.; Lane, S.N.; Spencer, R.G.M.; Wohl, E.; Sha, A.; Zhao, Y.; Miao, C.; Ning, M.; Yuan, L.; Ni, J.</b> (2026). Increasing river sediment concentration and flux across the pan-Arctic. <i>Nature Geoscience 19(5)</i>: 565-572. <a href=\"https://dx.doi.org/10.1038/s41561-026-01960-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01960-z</a>","StandardTitle":"Increasing river sediment concentration and flux across the pan-Arctic","AuthorsString":"Tian, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296269,"RR":"<b>Iaffaldano, G.; Davies, D.R.; DeMets, C.</b> (2018). Indian Ocean floor deformation induced by the Reunion plume rather than the Tibetan Plateau. <i>Nature Geoscience 11(5)</i>: 362-366. <a href=\"https://dx.doi.org/10.1038/s41561-018-0110-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0110-z</a>","StandardTitle":"Indian Ocean floor deformation induced by the Reunion plume rather than the Tibetan Plateau","AuthorsString":"Iaffaldano, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396167,"RR":"<b>Dong, C.; Noyelle, R.; Messori, G.; Gualandi, A.; Fery, L.; Yiou, P.; Vrac, M.; D’Andrea, F.; Camargo, S.J.; Coppola, E.; Balsamo, G.; Chen, C.; Faranda, D.; Mengaldo, G.</b> (2024). Indo-Pacific regional extremes aggravated by changes in tropical weather patterns. <i>Nature Geoscience 17(10)</i>: 979-986. <a href=\"https://dx.doi.org/10.1038/s41561-024-01537-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01537-8</a>","StandardTitle":"Indo-Pacific regional extremes aggravated by changes in tropical weather patterns","AuthorsString":"Dong, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":405429,"RR":"<b>Williams, J.R.; Giering, S.L.C.; Baker, C.A.; Pabortsava, K.; Briggs, N.; East, H.; Espinola, B.; Blackbird, S.; Le Moigne, F.A.C.; Villa-Alfageme, M.; Poulton, A.J.; Carvalho, F.; Pebody, C.; Saw, K.; Moore, C.M.; Henson, S.A.; Sanders, R.; Martin, A.P.</b> (2025). Inefficient transfer of diatoms through the subpolar Southern Ocean twilight zone. <i>Nature Geoscience 18(1)</i>: 72-77. <a href=\"https://dx.doi.org/10.1038/s41561-024-01602-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01602-2</a>","StandardTitle":"Inefficient transfer of diatoms through the subpolar Southern Ocean twilight zone","AuthorsString":"Williams, J.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":257822,"RR":"<b>Hu, A.; Meehl, G.; Otto-Bliesner, B.; Waelbroeck, C.; Han, W.; Loutre, M.-F.; Lambeck, K.; Mitrovica, J.; Rosenbloom, N.</b> (2010). Influence of Bering Strait flow and North Atlantic circulation on glacial sea-level changes. <i>Nature Geoscience 3(2)</i>: 118-121. <a href=\"https://dx.doi.org/10.1038/NGEO729\" target=\"_blank\">https://dx.doi.org/10.1038/NGEO729</a>","StandardTitle":"Influence of Bering Strait flow and North Atlantic circulation on glacial sea-level changes","AuthorsString":"Hu, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":349088,"RR":"<b>Petäjä, T.; Tabakova, K.; Manninen, A.; Ezhova, E.; O’Connor, E.; Moisseev, D.; Sinclair, V. A.; Backman, J.; Levula, J.; Luoma, K.; Virkkula, A.; Paramonov, M.; Räty, M.; Äijälä, M.; Heikkinen, L.; Ehn, M.; Sipilä, M.; Yli-Juuti, T.; Virtanen, A.; Ritsche, M.; Hickmon, N.; Pulik, G.; Rosenfeld, D.; Worsnop, D. R.; Bäck, J.; Kulmala, M.; Kerminen, V.-M.</b> (2022). Influence of biogenic emissions from boreal forests on aerosol–cloud interactions. <i>Nature Geoscience 15(1)</i>: 42-47. <a href=\"https://dx.doi.org/10.1038/s41561-021-00876-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00876-0</a>","StandardTitle":"Influence of biogenic emissions from boreal forests on aerosol–cloud interactions","AuthorsString":"Petäjä, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291793,"RR":"<b>Tréguer, P.; Bowler, C.; Moriceau, B.; Dutkiewicz, S.; Gehlen, M.; Aumont, O.; Bittner, L.; Dugdale, R.C.; Finkel, Z.V.; Iudicone, D.; Jahn, O.; Guidi, L.; Lasbleiz, M.; Lévy, M.; Pondaven, P.</b> (2017). Influence of diatom diversity on the ocean biological carbon pump. <i>Nature Geoscience 11(1)</i>: 27-37. <a href=\"https://dx.doi.org/10.1038/s41561-017-0028-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0028-x</a>","StandardTitle":"Influence of diatom diversity on the ocean biological carbon pump","AuthorsString":"Tréguer, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":245686,"RR":"<b>Allen, J.T.; Tippett, M.K.; Sobel, A.H.</b> (2015). Influence of the El Niño/Southern Oscillation on tornado and hail frequency in the United States. <i>Nature Geoscience 8(4)</i>: 278–283. <a href=\"http://dx.doi.org/10.1038/ngeo2385\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2385</a>","StandardTitle":"Influence of the El Niño/Southern Oscillation on tornado and hail frequency in the United States","AuthorsString":"Allen, J.T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":318167,"RR":"<b>Lyons, J.J.; Haney, M.M.; Fee, D.; Wech, A.G.; Waythomas, C.F.</b> (2019). Infrasound from giant bubbles during explosive submarine eruptions. <i>Nature Geoscience 12(11)</i>: 952-958. <a href=\"https://dx.doi.org/10.1038/s41561-019-0461-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0461-0</a>","StandardTitle":"Infrasound from giant bubbles during explosive submarine eruptions","AuthorsString":"Lyons, J.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396663,"RR":"<b>Nikeleit, V.; Mellage, A.; Bianchini, G.; Sauter, L.; Buessecker, S.; Gotterbarm, S.; Schad, M.; Konhauser, K.; Zerkle, A.L.; Sánchez-Baracaldo, P.; Kappler, A.; Bryce, C.</b> (2024). Inhibition of phototrophic iron oxidation by nitric oxide in ferruginous environments. <i>Nature Geoscience 17(11)</i>: 1169-1174. <a href=\"https://dx.doi.org/10.1038/s41561-024-01560-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01560-9</a>","StandardTitle":"Inhibition of phototrophic iron oxidation by nitric oxide in ferruginous environments","AuthorsString":"Nikeleit, V. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":306494,"RR":"<b>Chiodo, G.; Oehrlein, J.; Polvani, L.M.; Fyfe, J.C.; Smith, A.K.</b> (2019). Insignificant influence of the 11-year solar cycle on the North Atlantic Oscillation. <i>Nature Geoscience 12(2)</i>: 94-99. <a href=\"https://dx.doi.org/10.1038/s41561-018-0293-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0293-3</a>","StandardTitle":"Insignificant influence of the 11-year solar cycle on the North Atlantic Oscillation","AuthorsString":"Chiodo, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296077,"RR":"<b>Yin, Q.Z.; Berger, A.</b> (2010). Insolation and CO<sub>2</sub> contribution to the interglacial climate before and after the Mid-Brunhes Event. <i>Nature Geoscience 3(4)</i>: 243-246. <a href=\"https://dx.doi.org/10.1038/NGEO771\" target=\"_blank\">https://dx.doi.org/10.1038/NGEO771</a>","StandardTitle":"Insolation and CO<sub>2</sub> contribution to the interglacial climate before and after the Mid-Brunhes Event","AuthorsString":"Yin, Q.Z.; Berger, A.","BibLvlCode":"AS"},{"BRefID":323341,"RR":"<b>Beinlich, A.; John, T.; Vrijmoed, J.C.; Tominaga, M.; Magna, T.; Podladchikov, Y.Y.</b> (2020). Instantaneous rock transformations in the deep crust driven by reactive fluid flow. <i>Nature Geoscience 13(4)</i>: 307-311. <a href=\"https://dx.doi.org/10.1038/s41561-020-0554-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0554-9</a>","StandardTitle":"Instantaneous rock transformations in the deep crust driven by reactive fluid flow","AuthorsString":"Beinlich, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":351415,"RR":"<b>Fernández Castro, B.; Peña, M.; Nogueira, E.; Gilcoto, M.; Broullón, E.; Comesaña, A.; Bouffard, D.; Naveira Garabato, A.C.; Mouriño-Carballido, B.</b> (2022). Intense upper ocean mixing due to large aggregations of spawning fish. <i>Nature Geoscience 15(4)</i>: 287-292. <a href=\"https://dx.doi.org/10.1038/s41561-022-00916-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00916-3</a>","StandardTitle":"Intense upper ocean mixing due to large aggregations of spawning fish","AuthorsString":"Fernández Castro, B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":338975,"RR":"<b>Hu, K.; Huang, G.; Huang, P.; Kosaka, Y.; Xie, S.-P.</b> (2021). Intensification of El Niño-induced atmospheric anomalies under greenhouse warming. <i>Nature Geoscience 14(6)</i>: 377-382. <a href=\"https://dx.doi.org/10.1038/s41561-021-00730-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00730-3</a>","StandardTitle":"Intensification of El Niño-induced atmospheric anomalies under greenhouse warming","AuthorsString":"Hu, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":329214,"RR":"<b>Adusumilli, S.; Fricker, H.A.; Medley, B.; Padman, L.; Siegfried, M.R.</b> (2020). Interannual variations in meltwater input to the Southern Ocean from Antarctic ice shelves. <i>Nature Geoscience 13(9)</i>: 616-620. <a href=\"https://dx.doi.org/10.1038/s41561-020-0616-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0616-z</a>","StandardTitle":"Interannual variations in meltwater input to the Southern Ocean from Antarctic ice shelves","AuthorsString":"Adusumilli, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":348078,"RR":"<b>Landais, A.; Stenni, B.; Masson-Delmotte, V.; Jouzel, J.; Cauquoin, A.; Fourré, E.; Minster, B.; Selmo, E.; Extier, T.; Werner, M.; Vimeux, F.; Uemura, R.; Crotti, I.; Grisart, A.</b> (2021). Interglacial Antarctic–Southern Ocean climate decoupling due to moisture source area shifts. <i>Nature Geoscience 14(12)</i>: 918-923. <a href=\"https://dx.doi.org/10.1038/s41561-021-00856-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00856-4</a>","StandardTitle":"Interglacial Antarctic–Southern Ocean climate decoupling due to moisture source area shifts","AuthorsString":"Landais, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":231404,"RR":"<b>Collins, J.A.; Schefuss, E.; Heslop, D.; Mulitza, S.; Prange, M.; Zabel, M.; Tjallingii, R.; Dokken, T.M.; Huang, E.Q.; Mackensen, A.; Schulz, M.; Tian, J.; Zarriess, M.; Wefer, G.</b> (2011). Interhemispheric symmetry of the tropical African rainbelt over the past 23,000 years. <i>Nature Geoscience 4(1)</i>: 42-45. <a href=\"http://dx.doi.org/10.1038/NGEO1039\" target=\"_blank\">dx.doi.org/10.1038/NGEO1039</a>","StandardTitle":"Interhemispheric symmetry of the tropical African rainbelt over the past 23,000 years","AuthorsString":"Collins, J.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":286596,"RR":"<b>Wang, J.; Yang, B.</b> (2017). Internal and external forcing of multidecadal Atlantic climate variability over the past 1,200 years. <i>Nature Geoscience 10(7)</i>: 512-517. <a href=\"https://dx.doi.org/10.1038/ngeo2962\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2962</a>","StandardTitle":"Internal and external forcing of multidecadal Atlantic climate variability over the past 1,200 years","AuthorsString":"Wang, J.; Yang, B.","BibLvlCode":"AS"},{"BRefID":309972,"RR":"<b>Khazendar, A.; Fenty, I.G.; Carroll, D.; Gardner, A.S.; Lee, C.M.; Fukumori, I.; Wang, O.; Zhang, H.; Seroussi, H.; Moller, D.; Noël, B.P.Y.; van den Broeke, M.R.; Dinardo, S.; Willis, J.K.</b> (2019). Interruption of two decades of Jakobshavn Isbrae acceleration and thinning as regional ocean cools. <i>Nature Geoscience 12(4)</i>: 277-283. <a href=\"https://dx.doi.org/10.1038/s41561-019-0329-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0329-3</a>","StandardTitle":"Interruption of two decades of Jakobshavn Isbrae acceleration and thinning as regional ocean cools","AuthorsString":"Khazendar, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":298376,"RR":"<b>Hopwood, M.J.</b> (2018). Iron from ice. <i>Nature Geoscience 11(7)</i>: 462-462. <a href=\"https://dx.doi.org/10.1038/s41561-018-0167-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0167-8</a>","StandardTitle":"Iron from ice","AuthorsString":"Hopwood, M.J.","BibLvlCode":"AS"},{"BRefID":324020,"RR":"<b>Lesher, C.E.; Dannberg, J.; Barfod, G.H.; Bennett, N.R.; Glessner, J.J.G.; Lacks, D.J.; Brenan, J.M.</b> (2020). Iron isotope fractionation at the core–mantle boundary by thermodiffusion. <i>Nature Geoscience 13(5)</i>: 382-386. <a href=\"https://dx.doi.org/10.1038/s41561-020-0560-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0560-y</a>","StandardTitle":"Iron isotope fractionation at the core–mantle boundary by thermodiffusion","AuthorsString":"Lesher, C.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":283778,"RR":"<b>Fitzsimmons, J.N.; John, S.G.; Marsay, C.M.; Hoffman, C.L.; Nicholas, S.L.; Toner, B.M.; German, C.R.; Sherrell, R.M.</b> (2017). Iron persistence in a distal hydrothermal plume supported by dissolved–particulate exchange. <i>Nature Geoscience 10(3)</i>: 195-201. <a href=\"http://dx.doi.org/10.1038/ngeo2900\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2900</a>","StandardTitle":"Iron persistence in a distal hydrothermal plume supported by dissolved–particulate exchange","AuthorsString":"Fitzsimmons, J.N. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":283783,"RR":"<b>Michiels, C.C.; Darchambeau, F.; Roland, F.A.E.; Morana, C.; Llirós, M.; García-Armisen, T.; Thamdrup, B.; Borges, A.V.; Canfield, D.E.; Servais, P.; Descy, J.-P.; Crowe, S.A.</b> (2017). Iron-dependent nitrogen cycling in a ferruginous lake and the nutrient status of Proterozoic oceans. <i>Nature Geoscience 10(3)</i>: 217-221. <a href=\"https://dx.doi.org/10.1038/ngeo2886\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2886</a>","StandardTitle":"Iron-dependent nitrogen cycling in a ferruginous lake and the nutrient status of Proterozoic oceans","AuthorsString":"Michiels, C.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":321495,"RR":"<b>Bochet, O.; Bethencourt, L.; Dufresne, A.; Farasin, J.; Pédrot, M.; Labasque, T.; Chatton, E.; Lavenant, N.; Petton, C.; Abbott, B.W.; Aquilina, L.; Le Borgne, T.</b> (2020). Iron-oxidizer hotspots formed by intermittent oxic–anoxic fluid mixing in fractured rocks. <i>Nature Geoscience 13(2)</i>: 149-155. <a href=\"https://dx.doi.org/10.1038/s41561-019-0509-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0509-1</a>","StandardTitle":"Iron-oxidizer hotspots formed by intermittent oxic–anoxic fluid mixing in fractured rocks","AuthorsString":"Bochet, O. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":354967,"RR":"<b>Moore, L.J.; Murray, A.B.</b> (2022). Islands on the move. <i>Nature Geoscience 15(8)</i>: 602-603. <a href=\"https://dx.doi.org/10.1038/s41561-022-01000-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01000-6</a>","StandardTitle":"Islands on the move","AuthorsString":"Moore, L.J.; Murray, A.B.","BibLvlCode":"AS"},{"BRefID":394039,"RR":"<b>Novak, J.B.; Caballero-Gill, R.P.; Rose, R.M.; Herbert, T.D.; Dowsett, H.J.</b> (2024). Isotopic evidence against North Pacific Deep Water formation during late Pliocene warmth. <i>Nature Geoscience 17(8)</i>: 795-802. <a href=\"https://dx.doi.org/10.1038/s41561-024-01500-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01500-7</a>","StandardTitle":"Isotopic evidence against North Pacific Deep Water formation during late Pliocene warmth","AuthorsString":"Novak, J.B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":294041,"RR":"<b>Eickmann, B.; Hofmann, A.; Wille, M.; Bui, T.H.; Wing, B.A.; Schoenberg, R.</b> (2018). Isotopic evidence for oxygenated Mesoarchaean shallow oceans. <i>Nature Geoscience 11(2)</i>: 133-138. <a href=\"https://dx.doi.org/10.1038/s41561-017-0036-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0036-x</a>","StandardTitle":"Isotopic evidence for oxygenated Mesoarchaean shallow oceans","AuthorsString":"Eickmann, B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":406042,"RR":"(2025). Jet stream variations explain European hydroclimate extremes of the past 600 years. <i>Nature Geoscience 18(3)</i>: 203-204. <a href=\"https://dx.doi.org/10.1038/s41561-025-01655-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01655-x</a>","StandardTitle":"Jet stream variations explain European hydroclimate extremes of the past 600 years","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":349090,"RR":"<b>Nordt, L.; Breecker, D.; White, J.</b> (2022). Jurassic greenhouse ice-sheet fluctuations sensitive to atmospheric CO<sub>2</sub> dynamics. <i>Nature Geoscience 15(1)</i>: 54-59. <a href=\"https://dx.doi.org/10.1038/s41561-021-00858-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00858-2</a>","StandardTitle":"Jurassic greenhouse ice-sheet fluctuations sensitive to atmospheric CO<sub>2</sub> dynamics","AuthorsString":"Nordt, L.; Breecker, D.; White, J.","BibLvlCode":"AS"},{"BRefID":313844,"RR":"<b>Eichenseer, K.; Balthasar, U.; Smart, C.W.; Stander, J.; Haaga, K.A.; Kiessling, W.</b> (2019). Jurassic shift from abiotic to biotic control on marine ecological success. <i>Nature Geoscience 12(8)</i>: 638-642. <a href=\"https://dx.doi.org/10.1038/s41561-019-0392-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0392-9</a>","StandardTitle":"Jurassic shift from abiotic to biotic control on marine ecological success","AuthorsString":"Eichenseer, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":354966,"RR":"<b>Mariotti, G.; Hein, C.J.</b> (2022). Lag in response of coastal barrier-island retreat to sea-level rise. <i>Nature Geoscience 15(8)</i>: 633-638. <a href=\"https://dx.doi.org/10.1038/s41561-022-00980-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00980-9</a>","StandardTitle":"Lag in response of coastal barrier-island retreat to sea-level rise","AuthorsString":"Mariotti, G.; Hein, C.J.","BibLvlCode":"AS"},{"BRefID":437758,"RR":"<b>Zhong, Q.; Chan, J.C.L.; Duan, W.; Tu, S.; Li, J.; Gan, J.; Ding, R.</b> (2026). Landfalling tropical cyclones accelerate due to land–sea thermal and roughness contrasts. <i>Nature Geoscience 19(2)</i>: 159-164. <a href=\"https://dx.doi.org/10.1038/s41561-025-01891-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01891-1</a>","StandardTitle":"Landfalling tropical cyclones accelerate due to land–sea thermal and roughness contrasts","AuthorsString":"Zhong, Q. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":285914,"RR":"<b>Avery, M.A.; Davis, S.M.; Rosenlof, K.H.; Ye, H.; Dessler, A.E.</b> (2017). Large anomalies in lower stratospheric water vapour and ice during the 2015–2016 El Niño. <i>Nature Geoscience 10(6)</i>: 405-409. <a href=\"https://dx.doi.org/10.1038/ngeo2961\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2961</a>","StandardTitle":"Large anomalies in lower stratospheric water vapour and ice during the 2015–2016 El Niño","AuthorsString":"Avery, M.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":197761,"RR":"<b>Hegglin, M.I.; Shepherd, T.G.</b> (2009). Large climate-induced changes in ultraviolet index and stratosphere-to-troposphere ozone flux. <i>Nature Geoscience 2(10)</i>: 687-691. <a href=\"https://dx.doi.org/10.1038/NGEO604\" target=\"_blank\">https://dx.doi.org/10.1038/NGEO604</a>","StandardTitle":"Large climate-induced changes in ultraviolet index and stratosphere-to-troposphere ozone flux","AuthorsString":"Hegglin, M.I.; Shepherd, T.G.","BibLvlCode":"AS"},{"BRefID":411058,"RR":"<b>Luo, Yiqi; Wei, Ning; Lu, Xingjie; Zhou, Yu; Tao, Feng; Quan, Quan; Liao, Cuijuan; Jiang, Lifen; Xia, Jianyang; Huang, Yuanyuan; Niu, Shuli; Xu, Xiangtao; Sun, Ying; Zeng, Ning; Koven, Charles; Peng, Liqing; Davis, Steve; Smith, Pete; You, Fengqi; Jiang, Yu; Cheng, Lailiang; Houlton, Benjamin</b> (2025). Large CO<sub>2</sub> removal potential of woody debris preservation in managed forests. <i>Nature Geoscience 18(7)</i>: 675-681. <a href=\"https://dx.doi.org/10.1038/s41561-025-01731-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01731-2</a>","StandardTitle":"Large CO<sub>2</sub> removal potential of woody debris preservation in managed forests","AuthorsString":"Luo, Yiqi <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":339168,"RR":"<b>Hawkings, J.R.; Linhoff, B.S.; Wadham, J.L.; Stibal, M.; Lamborg, C.H.; Carling, G.T.; Lamarche-Gagnon, G.; Kohler, T.J.; Ward, R.; Hendry, K.R.; Falteisek, L.; Kellerman, A.M.; Cameron, K.A.; Hatton, J.E.; Tingey, S.; Holt, A.D.; Vinšová, P.; Hofer, S.; Bulínová, M.; Větrovský, T.; Meire, L.; Spencer, R.G.M.</b> (2021). Large subglacial source of mercury from the southwestern margin of the Greenland Ice Sheet. <i>Nature Geoscience 14(7)</i>: 496–502. <a href=\"https://dx.doi.org/10.1038/s41561-021-00753-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00753-w</a>","StandardTitle":"Large subglacial source of mercury from the southwestern margin of the Greenland Ice Sheet","AuthorsString":"Hawkings, J.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":439201,"RR":"<b>Cai, F.; Gerten, D.; Zhang, K.; Zhang, T.; Yang, S.; Kurths, J.</b> (2026). Large-scale aggregation of humid heatwaves exacerbated by coastal oceanic warming. <i>Nature Geoscience 19(5)</i>: 513-519. <a href=\"https://dx.doi.org/10.1038/s41561-026-01952-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01952-z</a>","StandardTitle":"Large-scale aggregation of humid heatwaves exacerbated by coastal oceanic warming","AuthorsString":"Cai, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":289767,"RR":"<b>Wallace, L.M.; Kaneko, Y.; Hreinsdóttir, S.; Hamling, I.; Peng, Z.; Bartlow, N.; D’Anastasio, E.; Fry, B.</b> (2017). Large-scale dynamic triggering of shallow slow slip enhanced by overlying sedimentary wedge. <i>Nature Geoscience 10(10)</i>: 765-770. <a href=\"https://dx.doi.org/10.1038/ngeo3021\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3021</a>","StandardTitle":"Large-scale dynamic triggering of shallow slow slip enhanced by overlying sedimentary wedge","AuthorsString":"Wallace, L.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":319475,"RR":"<b>Barruol, G.; Sigloch, K.; Scholz, J.-R.; Mazzullo, A.; Stutzmann, E.; Montagner, J.-P.; Kiselev, S.; Fontaine, F.R.; Michon, L.; Deplus, Ch.; Dyment, J.</b> (2019). Large-scale flow of Indian Ocean asthenosphere driven by Réunion plume. <i>Nature Geoscience 12(12)</i>: 1043-1049. <a href=\"https://dx.doi.org/10.1038/s41561-019-0479-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0479-3</a>","StandardTitle":"Large-scale flow of Indian Ocean asthenosphere driven by Réunion plume","AuthorsString":"Barruol, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":411043,"RR":"<b>Teder, N.J.; Bennetts, L.G.; Reid, P.A.; Massom, R.A.; Pitt, J.P.A.; Scambos, T.A.; Fraser, A.D.</b> (2025). Large-scale ice-shelf calving events follow prolonged amplifications in flexure. <i>Nature Geoscience 18(7)</i>: 599-606. <a href=\"https://dx.doi.org/10.1038/s41561-025-01713-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01713-4</a>","StandardTitle":"Large-scale ice-shelf calving events follow prolonged amplifications in flexure","AuthorsString":"Teder, N.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":302858,"RR":"<b>Whalen, C.B.; MacKinnon, J.A.; Talley, L.D.</b> (2018). Large-scale impacts of the mesoscale environment on mixing from wind-driven internal waves. <i>Nature Geoscience 11(11)</i>: 842-847. <a href=\"https://dx.doi.org/10.1038/s41561-018-0213-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0213-6</a>","StandardTitle":"Large-scale impacts of the mesoscale environment on mixing from wind-driven internal waves","AuthorsString":"Whalen, C.B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396664,"RR":"<b>Doucet, L.S.; Li, Z.X.</b> (2024). Large-scale mantle heterogeneity as a legacy of plate tectonic supercycles. <i>Nature Geoscience 17(11)</i>: 1175-1181. <a href=\"https://dx.doi.org/10.1038/s41561-024-01558-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01558-3</a>","StandardTitle":"Large-scale mantle heterogeneity as a legacy of plate tectonic supercycles","AuthorsString":"Doucet, L.S.; Li, Z.X.","BibLvlCode":"AS"},{"BRefID":243206,"RR":"<b>DeVries, T.; Deutsch, C.</b> (2014). Large-scale variations in the stoichiometry of marine organic matter respiration. <i>Nature Geoscience 7(12)</i>: 890–894. <a href=\"http://dx.doi.org/10.1038/ngeo2300\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2300</a>","StandardTitle":"Large-scale variations in the stoichiometry of marine organic matter respiration","AuthorsString":"DeVries, T.; Deutsch, C.","BibLvlCode":"AS"},{"BRefID":323343,"RR":"<b>Oryan, B.; Buck, W.E.</b> (2020). Larger tsunamis from megathrust earthquakes where slab dip is reduced. <i>Nature Geoscience 13(4)</i>: 319-324. <a href=\"https://dx.doi.org/10.1038/s41561-020-0553-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0553-x</a>","StandardTitle":"Larger tsunamis from megathrust earthquakes where slab dip is reduced","AuthorsString":"Oryan, B.; Buck, W.E.","BibLvlCode":"AS"},{"BRefID":329217,"RR":"<b>Yu, J.; Menviel, L.; Jin, Z.D.; Anderson, R.F.; Jian, Z.; Piotrowski, A.M.; Ma, X.; Rohling, E.J.; Zhang, F.; Marino, G.; McManus, J.F.</b> (2020). Last glacial atmospheric CO<sub>2</sub> decline due to widespread Pacific deep-water expansion. <i>Nature Geoscience 13(9)</i>: 628-633. <a href=\"https://dx.doi.org/10.1038/s41561-020-0610-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0610-5</a>","StandardTitle":"Last glacial atmospheric CO<sub>2</sub> decline due to widespread Pacific deep-water expansion","AuthorsString":"Yu, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":356608,"RR":"<b>Obreht, I.; De Vleeschouwer, D.; Wörmer, L.; Kucera, M.; Varma, D.; Prange, M.; Laepple, T.; Wendt, J.; Nandini-Weiss, S.D.; Schulz, H.; Hinrichs, K.-U.</b> (2022). Last Interglacial decadal sea surface temperature variability in the eastern Mediterranean. <i>Nature Geoscience 15(10)</i>: 812-818. <a href=\"https://dx.doi.org/10.1038/s41561-022-01016-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01016-y</a>","StandardTitle":"Last Interglacial decadal sea surface temperature variability in the eastern Mediterranean","AuthorsString":"Obreht, I. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":313847,"RR":"<b>Brönnimann, S.; Franke, J.; Nussbaumer, S.U.; Zumbühl, H.J.; Steiner, D.; Trachsel, M.; Hegerl, G.C.; Schurer, A.; Worni, M.; Malik, A.; Flückiger, J.; Raible, C.C.</b> (2019). Last phase of the Little Ice Age forced by volcanic eruptions. <i>Nature Geoscience 12(8)</i>: 650-656. <a href=\"https://dx.doi.org/10.1038/s41561-019-0402-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0402-y</a>","StandardTitle":"Last phase of the Little Ice Age forced by volcanic eruptions","AuthorsString":"Brönnimann, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":436566,"RR":"<b>Moseley, G.E.; Koltai, G.; Baker, J.L.; Wang, J.; Stoll, H.; Donner, A.; Friedrich, L.; Spötl, C.; Smith, M.P.; Scholz, D.; Cheng, H.; Hartland, A.; Hejny, C.; Edwards, R.L.</b> (2025). Late Miocene Arctic warmth and terrestrial climate recorded by North Greenland speleothems. <i>Nature Geoscience 18(12)</i>: 1252-1258. <a href=\"https://dx.doi.org/10.1038/s41561-025-01822-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01822-0</a>","StandardTitle":"Late Miocene Arctic warmth and terrestrial climate recorded by North Greenland speleothems","AuthorsString":"Moseley, G.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":354974,"RR":"<b>Brown, R.M.; Chalk, T.B.; Crocker, A.J.; Wilson, P.A.; Foster, G.L.</b> (2022). Late Miocene cooling coupled to carbon dioxide with Pleistocene-like climate sensitivity. <i>Nature Geoscience 15(8)</i>: 664-670. <a href=\"https://dx.doi.org/10.1038/s41561-022-00982-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00982-7</a>","StandardTitle":"Late Miocene cooling coupled to carbon dioxide with Pleistocene-like climate sensitivity","AuthorsString":"Brown, R.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":365453,"RR":"<b>Verret, M.; Trinh-Le, C.; Dickinson, W.; Norton, K.; Lacelle, D.; Christl, M.; Levy, R.; Naish, T.</b> (2023). Late Miocene onset of hyper-aridity in East Antarctica indicated by meteoric beryllium-10 in permafrost. <i>Nature Geoscience 16(6)</i>: 492-498. <a href=\"https://dx.doi.org/10.1038/s41561-023-01193-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01193-4</a>","StandardTitle":"Late Miocene onset of hyper-aridity in East Antarctica indicated by meteoric beryllium-10 in permafrost","AuthorsString":"Verret, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":383522,"RR":"<b>Evangelinos, Dimitris; Etourneau, Johan; van de Flierdt, Tina; Crosta, Xavier; Jeandel, Catherine; Flores, José-Abel; Harwood, David M.; Valero, Luis; Ducassou, Emmanuelle; Sauermilch, Isabel; Klocker, Andreas; Cacho, Isabel; Pena, Leopoldo D.; Kreissig, Katharina; Benoit, Mathieu; Belhadj, Moustafa; Paredes, Eduardo; Garcia-Solsona, Ester; López-Quirós, Adrián; Salabarnada, Ariadna; Escutia, Carlota</b> (2024). Late Miocene onset of the modern Antarctic Circumpolar Current. <i>Nature Geoscience 17(2)</i>: 165-170. <a href=\"https://dx.doi.org/10.1038/s41561-023-01356-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01356-3</a>","StandardTitle":"Late Miocene onset of the modern Antarctic Circumpolar Current","AuthorsString":"Evangelinos, Dimitris <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":348079,"RR":"<b>Longman, J.; Mills, B.J.W.; Manners, H.R.; Gernon, T.M.; Palmer, M.R.</b> (2021). Late Ordovician climate change and extinctions driven by elevated volcanic nutrient supply. <i>Nature Geoscience 14(12)</i>: 924-929. <a href=\"https://dx.doi.org/10.1038/s41561-021-00855-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00855-5</a>","StandardTitle":"Late Ordovician climate change and extinctions driven by elevated volcanic nutrient supply","AuthorsString":"Longman, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366132,"RR":"<b>Hobart, B.; Lisiecki, L.E.; Rand, D.; Lee, T.; Lawrence, C.E.</b> (2023). Late Pleistocene 100-kyr glacial cycles paced by precession forcing of summer insolation. <i>Nature Geoscience 16(8)</i>: 717-722. <a href=\"https://dx.doi.org/10.1038/s41561-023-01235-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01235-x</a>","StandardTitle":"Late Pleistocene 100-kyr glacial cycles paced by precession forcing of summer insolation","AuthorsString":"Hobart, B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":338980,"RR":"(2021). Lessons from a hot past. <i>Nature Geoscience 14(6)</i>: 355-355. <a href=\"https://dx.doi.org/10.1038/s41561-021-00776-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00776-3</a>","StandardTitle":"Lessons from a hot past","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":245785,"RR":"<b>Orcutt, B.N.</b> (2015). Life in the deepest depths. <i>Nature Geoscience 8(4)</i>: 258–259. <a href=\"http://dx.doi.org/10.1038/ngeo2378\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2378</a>","StandardTitle":"Life in the deepest depths","AuthorsString":"Orcutt, B.N.","BibLvlCode":"AS"},{"BRefID":391166,"RR":"<b>Evans, C.; Taillardat, P.</b> (2024). Light on dark waters. <i>Nature Geoscience 17(3)</i>: 174-175. <a href=\"https://dx.doi.org/10.1038/s41561-024-01376-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01376-7</a>","StandardTitle":"Light on dark waters","AuthorsString":"Evans, C.; Taillardat, P.","BibLvlCode":"AS"},{"BRefID":321905,"RR":"<b>Johnson, B.W.; Wing, B.A.</b> (2020). Limited Archaean continental emergence reflected in an early Archaean <sup>18</sup>O-enriched ocean. <i>Nature Geoscience 13</i>: 243-248. <a href=\"https://dx.doi.org/10.1038/s41561-020-0538-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0538-9</a>","StandardTitle":"Limited Archaean continental emergence reflected in an early Archaean <sup>18</sup>O-enriched ocean","AuthorsString":"Johnson, B.W.; Wing, B.A.","BibLvlCode":"AS"},{"BRefID":359607,"RR":"<b>Amano, C.; Zhao, Z.; Sintes, E.; Reinthaler, T.; Stefanschitz, J.; Kisadur, M.; Utsumi, M.; Herndl, G.J.</b> (2022). Limited carbon cycling due to high-pressure effects on the deep-sea microbiome. <i>Nature Geoscience 15(12)</i>: 1041-1047. <a href=\"https://dx.doi.org/10.1038/s41561-022-01081-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01081-3</a>","StandardTitle":"Limited carbon cycling due to high-pressure effects on the deep-sea microbiome","AuthorsString":"Amano, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":405772,"RR":"<b>Fischer, H.; Burke, A.; Rae, J.; Sugden, P.J.; Erhardt, T.; Twarloh, B.; Hörhold, M.; Freitag, J.; Markle, B.; Severi, M.; Hansson, M.; Savarino, J.; Pryer, H.; Doyle, E.; Wolff, E.</b> (2025). Limited decrease of Southern Ocean sulfur productivity across the penultimate termination. <i>Nature Geoscience 18(2)</i>: 160-166. <a href=\"https://dx.doi.org/10.1038/s41561-024-01619-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01619-7</a>","StandardTitle":"Limited decrease of Southern Ocean sulfur productivity across the penultimate termination","AuthorsString":"Fischer, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":355460,"RR":"<b>Camerlenghi, A.</b> (2022). Lingering end to a salinity crisis. <i>Nature Geoscience 15(9)</i>: 688–690. <a href=\"https://dx.doi.org/10.1038/s41561-022-01002-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01002-4</a>","StandardTitle":"Lingering end to a salinity crisis","AuthorsString":"Camerlenghi, A.","BibLvlCode":"AS"},{"BRefID":217874,"RR":"<b>Törnqvist, T.E.; Hijma, M.P.</b> (2012). Links between early Holocene ice-sheet decay, sea-level rise and abrupt climate change. <i>Nature Geoscience 5(9)</i>: 601-606. <a href=\"http://dx.doi.org/10.1038/ngeo1536\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1536</a>","StandardTitle":"Links between early Holocene ice-sheet decay, sea-level rise and abrupt climate change","AuthorsString":"Törnqvist, T.E.; Hijma, M.P.","BibLvlCode":"AS"},{"BRefID":365449,"RR":"<b>Keller, D.S.; Tassara, S.; Robbins, L.J.; Lee, C.-T.A.; Ague, J.J.; Dasgupta, R.</b> (2023). Links between large igneous province volcanism and subducted iron formations. <i>Nature Geoscience 16(6)</i>: 527-533. <a href=\"https://dx.doi.org/10.1038/s41561-023-01188-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01188-1</a>","StandardTitle":"Links between large igneous province volcanism and subducted iron formations","AuthorsString":"Keller, D.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291305,"RR":"<b>Han, S.; Bangs, N.L.; Carbotte, S.M.; Saffer, D.M.; Gibson, J.C.</b> (2017). Links between sediment consolidation and Cascadia megathrust slip behaviour. <i>Nature Geoscience 10(12)</i>: 954-959. <a href=\"https://dx.doi.org/10.1038/s41561-017-0007-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0007-2</a>","StandardTitle":"Links between sediment consolidation and Cascadia megathrust slip behaviour","AuthorsString":"Han, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":240068,"RR":"<b>MacCready, P.</b> (2014). Links between surface and abyss. <i>Nature Geoscience 7(8)</i>: 554-555. <a href=\"http://dx.doi.org/10.1038/ngeo2210\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2210</a>","StandardTitle":"Links between surface and abyss","AuthorsString":"MacCready, P.","BibLvlCode":"AS"},{"BRefID":252690,"RR":"<b>Emile-Geay, J.; Cobb, K.M.; Carré, M.; Braconnot, P.; Leloup, J.; Zhou, Y.; Harrison, S.P.; Corrège, T.; McGregor, H.V.; Collins, M.; Driscoll, R.; Elliot, M.; Schneider, B.; Tudhope, A.</b> (2015). Links between tropical Pacific seasonal, interannual and orbital variability during the Holocene. <i>Nature Geoscience 9(2)</i>: 168-173. <a href=\"http://dx.doi.org/10.1038/ngeo2608\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2608</a>","StandardTitle":"Links between tropical Pacific seasonal, interannual and orbital variability during the Holocene","AuthorsString":"Emile-Geay, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":368748,"RR":"(2023). Locally surprising megafloods in Europe can be anticipated from continent-wide observations. <i>Nature Geoscience 16(11)</i>: 942-943. <a href=\"https://dx.doi.org/10.1038/s41561-023-01301-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01301-4</a>","StandardTitle":"Locally surprising megafloods in Europe can be anticipated from continent-wide observations","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":367824,"RR":"<b>Xiao, S.; Cui, Y.; Brahney, J.; Mahowald, N.M.; Li, Q.</b> (2023). Long-distance atmospheric transport of microplastic fibres influenced by their shapes. <i>Nature Geoscience 16(10)</i>: 863-870. <a href=\"https://dx.doi.org/10.1038/s41561-023-01264-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01264-6</a>","StandardTitle":"Long-distance atmospheric transport of microplastic fibres influenced by their shapes","AuthorsString":"Xiao, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":356604,"RR":"<b>Scaife, A.A.; Hermanson, L.; van Niekerk, A.; Andrews, M.; Baldwin, M.P.; Belcher, S.; Bett, P.; Comer, R.E.; Dunstone, N.J.; Geen, R.; Hardiman, S.C.; Ineson, S.; Knight, J.; Nie, Y.; Ren, H.-L.; Smith, D.</b> (2022). Long-range predictability of extratropical climate and the length of day. <i>Nature Geoscience 15(10)</i>: 789-793. <a href=\"https://dx.doi.org/10.1038/s41561-022-01037-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01037-7</a>","StandardTitle":"Long-range predictability of extratropical climate and the length of day","AuthorsString":"Scaife, A.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":404835,"RR":"<b>Zhang, W.; Porz, L.; Yilmaz, R.; Wallmann, K.; Spiegel, T.; Neumann, A.; Holtappels, M.; Kasten, S.; Kuhlmann, J.; Ziebarth, N.; Taylor, B.; Ho-Hagemann, H.T.M.; Bockelmann, F-D.; Daewel, U.; Bernhardt, L.; Schrum, C.</b> (2024). Long-term carbon storage in shelf sea sediments reduced by intensive bottom trawling. <i>Nature Geoscience 17(12)</i>: 1268-1276. <a href=\"https://dx.doi.org/10.1038/s41561-024-01581-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01581-4</a>","StandardTitle":"Long-term carbon storage in shelf sea sediments reduced by intensive bottom trawling","AuthorsString":"Zhang, W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":247384,"RR":"<b>Whittaker, J.M.; Afonso, J.C.; Masterton, S.; Muller, R.D.; Wessel, P.; Williams, S.E.; Seton, M.</b> (2015). Long-term interaction between mid-ocean ridges and mantle plumes. <i>Nature Geoscience 8(6)</i>: 479–483. <a href=\"http://dx.doi.org/10.1038/ngeo2437\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2437</a>","StandardTitle":"Long-term interaction between mid-ocean ridges and mantle plumes","AuthorsString":"Whittaker, J.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":329543,"RR":"<b>Shaffer, G.; Olsen, S.M.; Pedersen, J.O.P.</b> (2009). Long-term ocean oxygen depletion in response to carbon dioxide emissions from fossil fuels. <i>Nature Geoscience 2(2)</i>: 105-109. <a href=\"https://dx.doi.org/10.1038/ngeo420\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo420</a>","StandardTitle":"Long-term ocean oxygen depletion in response to carbon dioxide emissions from fossil fuels","AuthorsString":"Shaffer, G.; Olsen, S.M.; Pedersen, J.O.P.","BibLvlCode":"AS"},{"BRefID":363737,"RR":"<b>Mound, J.E.; Davies, C.J.</b> (2023). Longitudinal structure of Earth’s magnetic field controlled by lower mantle heat flow. <i>Nature Geoscience 16(4)</i>: 380-385. <a href=\"https://dx.doi.org/10.1038/s41561-023-01148-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01148-9</a>","StandardTitle":"Longitudinal structure of Earth’s magnetic field controlled by lower mantle heat flow","AuthorsString":"Mound, J.E.; Davies, C.J.","BibLvlCode":"AS"},{"BRefID":404827,"RR":"<b>Super, J.</b> (2024). Looking toward the future of ocean drilling. <i>Nature Geoscience 17(12)</i>: 1189-1192. <a href=\"https://dx.doi.org/10.1038/s41561-024-01600-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01600-4</a>","StandardTitle":"Looking toward the future of ocean drilling","AuthorsString":"Super, J.","BibLvlCode":"AS"},{"BRefID":246331,"RR":"<b>Houston, H.</b> (2015). Low friction and fault weakening revealed by rising sensitivity of tremor to tidal stress. <i>Nature Geoscience 8(5)</i>: 409-415. <a href=\"http://dx.doi.org/10.1038/ngeo2419\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2419</a>","StandardTitle":"Low friction and fault weakening revealed by rising sensitivity of tremor to tidal stress","AuthorsString":"Houston, H.","BibLvlCode":"AS"},{"BRefID":408327,"RR":"<b>Wu, J.; Cronin, S.J.; Brenna, M.; Park, S.-H.; Pontesilli, A.; Ukstins, I.A.; Adams, D.; Paredes-Mariño, J.; Hamilton, K.; Huebsch, M.; González-García, D.; Firth, C.; White, J.D.L.; Nichols, A.R.L.; Plank, T.; Vongsvivut, J.; Klein, A.; Ramos, F.; Latu’ila, F.; Kula, T.</b> (2025). Low sulfur emissions from 2022 Hunga eruption due to seawater–magma interactions. <i>Nature Geoscience 18(6)</i>: 518-524. <a href=\"https://dx.doi.org/10.1038/s41561-025-01691-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01691-7</a>","StandardTitle":"Low sulfur emissions from 2022 Hunga eruption due to seawater–magma interactions","AuthorsString":"Wu, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":353958,"RR":"<b>Guo, P.; Singh, S.C.; Vaddineni, V.A.; Grevemeyer, I.; Saygin, E.</b> (2022). Lower oceanic crust formed by in situ melt crystallization revealed by seismic layering. <i>Nature Geoscience 15(7)</i>: 591-596. <a href=\"https://dx.doi.org/10.1038/s41561-022-00963-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00963-w</a>","StandardTitle":"Lower oceanic crust formed by in situ melt crystallization revealed by seismic layering","AuthorsString":"Guo, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":289769,"RR":"<b>Sternai, P.; Caricchi, L.; Garcia-Castellanos, D.; Jolivet, L.; Sheldrake, T.E.; Castelltort, S.</b> (2017). Magmatic pulse driven by sea-level changes associated with the Messinian salinity crisis. <i>Nature Geoscience 10(10)</i>: 783–787. <a href=\"https://dx.doi.org/10.1038/ngeo3032\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3032</a>","StandardTitle":"Magmatic pulse driven by sea-level changes associated with the Messinian salinity crisis","AuthorsString":"Sternai, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":368751,"RR":"<b>Zhang, X.; Brown, E.L.; Zhang, J.; Lin, J.; Bao, X.; Sager, W.W.</b> (2023). Magmatism of Shatsky Rise controlled by plume–ridge interaction. <i>Nature Geoscience 16(11)</i>: 1061-1069. <a href=\"https://dx.doi.org/10.1038/s41561-023-01286-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01286-0</a>","StandardTitle":"Magmatism of Shatsky Rise controlled by plume–ridge interaction","AuthorsString":"Zhang, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":419029,"RR":"<b>Stevens, R.E.; Reade, H.; Sayle, K.L.; Tripp, J.A.; Frémondeau, D.; Lister, A.; Barnes, I.; Germonpre, M.; Street, M.; Murton, J.B.; Bottrell, S.H.; James, D.H.; Higham, T.F.G.</b> (2025). Major excursions in sulfur isotopes linked to permafrost change in Eurasia during the last 50,000 years. <i>Nature Geoscience 18(10)</i>: 961-965. <a href=\"https://dx.doi.org/10.1038/s41561-025-01760-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01760-x</a>","StandardTitle":"Major excursions in sulfur isotopes linked to permafrost change in Eurasia during the last 50,000 years","AuthorsString":"Stevens, R.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":437133,"RR":"<b>Kong, X.; Lechtenfeld, O.J.; Kaesler, J.M.; Granskog, M.A.; Stedmon, C.A.; Graeve, M.; Koch, B.P.</b> (2026). Major terrestrial contribution to the dissolved organic carbon budget in the Arctic Ocean. <i>Nature Geoscience 19(1)</i>: 90-98. <a href=\"https://dx.doi.org/10.1038/s41561-025-01847-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01847-5</a>","StandardTitle":"Major terrestrial contribution to the dissolved organic carbon budget in the Arctic Ocean","AuthorsString":"Kong, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":349756,"RR":"<b>Basu, N.B.; Van Meter, K.J.; Byrnes, D.K.; Van Cappellen, P.; Brouwer, R.; Jacobsen, B.H.; Jarsjö, J.; Rudolph, D.L.; Cunha, M.C.; Nelson, N.; Bhattacharya, R.; Destouni, G.; Olsen, S.B.</b> (2022). Managing nitrogen legacies to accelerate water quality improvement. <i>Nature Geoscience 15(2)</i>: 97-105. <a href=\"https://dx.doi.org/10.1038/s41561-021-00889-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00889-9</a>","StandardTitle":"Managing nitrogen legacies to accelerate water quality improvement","AuthorsString":"Basu, N.B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":306500,"RR":"<b>Simard, M.; Fatoyinbo, L.; Smetanka, C.; Rivera-Monroy, V.H.; Castañeda-Moya, E.; Thomas, N.; Van der Stocken, T.</b> (2019). Mangrove canopy height globally related to precipitation, temperature and cyclone frequency. <i>Nature Geoscience 12(1)</i>: 40-45. <a href=\"https://dx.doi.org/10.1038/s41561-018-0279-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0279-1</a>","StandardTitle":"Mangrove canopy height globally related to precipitation, temperature and cyclone frequency","AuthorsString":"Simard, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":436572,"RR":"<b>Qin, G.; Lu, Z.; Sanders, C.; Zhang, J.; Gan, S.; Zhou, J.; Huang, X.; He, H.; Yu, M.; Li, H.; Macreadie, P.I.; Wang, F.</b> (2025). Mangrove sediment carbon burial offset by methane emissions from mangrove tree stems. <i>Nature Geoscience 18(12)</i>: 1224-1231. <a href=\"https://dx.doi.org/10.1038/s41561-025-01848-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01848-4</a>","StandardTitle":"Mangrove sediment carbon burial offset by methane emissions from mangrove tree stems","AuthorsString":"Qin, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296434,"RR":"<b>Donato, D.C.; Kauffman, J.B.; Murdiyarso, D.; Kumianto, S.; Stidham, M.; Kanninen, M.</b> (2011). Mangroves among the most carbon-rich forests in the tropics. <i>Nature Geoscience 4(5)</i>: 293-297. <a href=\"https://dx.doi.org/10.1038/ngeo1123\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo1123</a>","StandardTitle":"Mangroves among the most carbon-rich forests in the tropics","AuthorsString":"Donato, D.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":320521,"RR":"<b>Farinotti, D.; Immerzeel, W.W.; de Kok, R.J.; Quincey, D.J.; Dehecq, A.</b> (2020). Manifestations and mechanisms of the Karakoram glacier Anomaly. <i>Nature Geoscience 13(1)</i>: 8-16. <a href=\"https://dx.doi.org/10.1038/s41561-019-0513-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0513-5</a>","StandardTitle":"Manifestations and mechanisms of the Karakoram glacier Anomaly","AuthorsString":"Farinotti, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":438830,"RR":"<b>Duan, W.-Y.; Connolly, J.A.D.; van Keken, P.E.; Gerya, T.; Schertl, H.-P.; Willner, A.P.; Li, X.-P.; Li, S.-Z.</b> (2026). Mantle oxidation influenced by reduction-oxidation budget of Mariana-type subduction zones. <i>Nature Geoscience 19(4)</i>: 470-477. <a href=\"https://dx.doi.org/10.1038/s41561-026-01939-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01939-w</a>","StandardTitle":"Mantle oxidation influenced by reduction-oxidation budget of Mariana-type subduction zones","AuthorsString":"Duan, W.-Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":211514,"RR":"<b>Koppers, A.A.P.</b> (2011). Mantle plumes persevere. <i>Nature Geoscience 4(12)</i>: 816-817. <a href=\"http://dx.doi.org/10.1038/ngeo1334\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1334</a>","StandardTitle":"Mantle plumes persevere","AuthorsString":"Koppers, A.A.P.","BibLvlCode":"AS"},{"BRefID":411055,"RR":"<b>Watts, E.J.; Rees, R.; Jonathan, P.; Keir, D.; Taylor, R.N.; Siegburg, M.; Chambers, E.L.; Pagli, C.; Cooper, M.J.; Michalik, A.; Milton, J.A.; Hincks, T.K.; Gebru, E.F.; Ayele, A.; Abebe, B.; Gernon, T.M.</b> (2025). Mantle upwelling at Afar triple junction shaped by overriding plate dynamics. <i>Nature Geoscience 18(7)</i>: 661-669. <a href=\"https://dx.doi.org/10.1038/s41561-025-01717-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01717-0</a>","StandardTitle":"Mantle upwelling at Afar triple junction shaped by overriding plate dynamics","AuthorsString":"Watts, E.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":363321,"RR":"<b>Padrón-Navarta, J.A.; López Sánchez-Vizcaíno, V.; Menzel, M.D.; Gómez-Pugnaire, M.T.; Garrido, C.J.</b> (2023). Mantle wedge oxidation from deserpentinization modulated by sediment-derived fluids. <i>Nature Geoscience 16(3)</i>: 268-275. <a href=\"https://dx.doi.org/10.1038/s41561-023-01127-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01127-0</a>","StandardTitle":"Mantle wedge oxidation from deserpentinization modulated by sediment-derived fluids","AuthorsString":"Padrón-Navarta, J.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":308735,"RR":"<b>Kempton, K.D.</b> (2019). Map of the underworld. <i>Nature Geoscience 12(3)</i>: 151-152. <a href=\"https://dx.doi.org/10.1038/s41561-019-0321-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0321-y</a>","StandardTitle":"Map of the underworld","AuthorsString":"Kempton, K.D.","BibLvlCode":"AS"},{"BRefID":396655,"RR":"<b>Koeve, W.; Landolfi, A.; Oschlies, A.; Frenger, I.</b> (2024). Marine carbon sink dominated by biological pump after temperature overshoot. <i>Nature Geoscience 17(11)</i>: 1093-1099. <a href=\"https://dx.doi.org/10.1038/s41561-024-01541-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01541-y</a>","StandardTitle":"Marine carbon sink dominated by biological pump after temperature overshoot","AuthorsString":"Koeve, W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":281765,"RR":"<b>Repeta, D.J.; Ferrón, S.; Sosa, O.A.; Johnson, C.G.; Repeta, L.D.; Acker, M.; DeLong, E.F.; Karl, D.M.</b> (2016). Marine methane paradox explained by bacterial degradation of dissolved organic matter. <i>Nature Geoscience 9(12)</i>: 884-887. <a href=\"http://dx.doi.org/10.1038/ngeo2837\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2837</a>","StandardTitle":"Marine methane paradox explained by bacterial degradation of dissolved organic matter","AuthorsString":"Repeta, D.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":330060,"RR":"<b>Boudinot, F.G.; Sepúlveda, J.</b> (2020). Marine organic carbon burial increased forest fire frequency during Oceanic Anoxic Event 2. <i>Nature Geoscience 13(10)</i>: 693-698. <a href=\"https://dx.doi.org/10.1038/s41561-020-0633-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0633-y</a>","StandardTitle":"Marine organic carbon burial increased forest fire frequency during Oceanic Anoxic Event 2","AuthorsString":"Boudinot, F.G.; Sepúlveda, J.","BibLvlCode":"AS"},{"BRefID":215657,"RR":"<b>Houghton, K.J.; Vafeidis, A.T.; Neumann, B.; Proelss, A.</b> (2010). Maritime boundaries in a rising sea. <i>Nature Geoscience 3(12)</i>: 813-816. <a href=\"http://dx.doi.org/10.1038/ngeo1029\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1029</a>","StandardTitle":"Maritime boundaries in a rising sea","AuthorsString":"Houghton, K.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":347900,"RR":"<b>Tognin, D.; D'Alpaos, A.; Marani, M.; Carniello, L.</b> (2021). Marsh resilience to sea-level rise reduced by storm-surge barriers in the Venice Lagoon. <i>Nature Geoscience 14(12)</i>: 906-911. <a href=\"https://dx.doi.org/10.1038/s41561-021-00853-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00853-7</a>","StandardTitle":"Marsh resilience to sea-level rise reduced by storm-surge barriers in the Venice Lagoon","AuthorsString":"Tognin, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":248283,"RR":"<b>Arévalo-Martínez, D.L.; Kock, A.; Löscher, C.R.; Schmitz, R.A.; Bange, H.W.</b> (2015). Massive nitrous oxide emissions from the tropical South Pacific Ocean. <i>Nature Geoscience 8(7)</i>: 530–533. <a href=\"http://dx.doi.org/10.1038/ngeo2469\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2469</a>","StandardTitle":"Massive nitrous oxide emissions from the tropical South Pacific Ocean","AuthorsString":"Arévalo-Martínez, D.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":415758,"RR":"<b>Bonino, G.; McAdam, R.; Athanasiadis, P.; Cavicchia, L.; Rodrigues, R.R.; Scoccimarro, E.; Tibaldi, S.; Masina, S.</b> (2025). Mediterranean summer marine heatwaves triggered by weaker winds under subtropical ridges. <i>Nature Geoscience 18(9)</i>: 848-853. <a href=\"https://dx.doi.org/10.1038/s41561-025-01762-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01762-9</a>","StandardTitle":"Mediterranean summer marine heatwaves triggered by weaker winds under subtropical ridges","AuthorsString":"Bonino, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":368749,"RR":"<b>Bertola, Miriam; Blöschl, Günter; Bohac, Milon; Borga, Marco; Castellarin, Attilio; Chirico, Giovanni B.; Claps, Pierluigi; Dallan, Eleonora; Danilovich, Irina; Ganora, Daniele; Gorbachova, Liudmyla; Ledvinka, Ondrej; Mavrova-Guirguinova, Maria; Montanari, Alberto; Ovcharuk, Valeriya; Viglione, Alberto; Volpi, Elena; Arheimer, Berit; Aronica, Giuseppe Tito; Bonacci, Ognjen; Čanjevac, Ivan; Csik, Andras; Frolova, Natalia; Gnandt, Boglarka; Gribovszki, Zoltan; Gül, Ali; Günther, Knut; Guse, Björn; Hannaford, Jamie; Harrigan, Shaun; Kireeva, Maria; Kohnová, Silvia; Komma, Jürgen; Kriauciuniene, Jurate; Kronvang, Brian; Lawrence, Deborah; Lüdtke, Stefan; Mediero, Luis; Merz, Bruno; Molnar, Peter; Murphy, Conor; Oskoruš, Dijana; Osuch, Marzena; Parajka, Juraj; Pfister, Laurent; Radevski, Ivan; Sauquet, Eric; Schröter, Kai; Šraj, Mojca; Szolgay, Jan; Turner, Stephen; Valent, Peter; Veijalainen, Noora; Ward, Philip J.; Willems, Patrick; Zivkovic, Nenad</b> (2023). Megafloods in Europe can be anticipated from observations in hydrologically similar catchments. <i>Nature Geoscience 16(11)</i>: 982-988. <a href=\"https://dx.doi.org/10.1038/s41561-023-01300-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01300-5</a>","StandardTitle":"Megafloods in Europe can be anticipated from observations in hydrologically similar catchments","AuthorsString":"Bertola, Miriam <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":337159,"RR":"(2021). Megathrusts exhumed. <i>Nature Geoscience 14(5)</i>: 255. <a href=\"https://hdl.handle.net/10.1038/s41561-021-00757-6\" target=\"_blank\">https://hdl.handle.net/10.1038/s41561-021-00757-6</a>","StandardTitle":"Megathrusts exhumed","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":367807,"RR":"<b>Wengrove, M.E.; Pettit, E.C.; Nash, J.D.; Jackson, R.H.; Skyllingstad, E.D.</b> (2023). Melting of glacier ice enhanced by bursting air bubbles. <i>Nature Geoscience 16(10)</i>: 871-876. <a href=\"https://dx.doi.org/10.1038/s41561-023-01262-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01262-8</a>","StandardTitle":"Melting of glacier ice enhanced by bursting air bubbles","AuthorsString":"Wengrove, M.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":406046,"RR":"<b>Coonin, A.N.; Lau, H.C.P.; Coulson, S.</b> (2025). Meltwater Pulse 1A sea-level-rise patterns explained by global cascade of ice loss. <i>Nature Geoscience 18(3)</i>: 254-259. <a href=\"https://dx.doi.org/10.1038/s41561-025-01648-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01648-w</a>","StandardTitle":"Meltwater Pulse 1A sea-level-rise patterns explained by global cascade of ice loss","AuthorsString":"Coonin, A.N.; Lau, H.C.P.; Coulson, S.","BibLvlCode":"AS"},{"BRefID":381169,"RR":"<b>Torres-Rodriguez, N.; Yuan, J.; Petersen, S.; Dufour, A.; González-Santana, D.; Chavagnac, V.; Planquette, H.; Horvat, M.; Amouroux, D.; Cathalot, C.; Pelleter, E.; Sun, R.; Sonke, J.E.; Luther, G.W.; Heimbürger-Boavida, L.-E.</b> (2024). Mercury fluxes from hydrothermal venting at mid-ocean ridges constrained by measurements. <i>Nature Geoscience 17(1)</i>: 51-57. <a href=\"https://dx.doi.org/10.1038/s41561-023-01341-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01341-w</a>","StandardTitle":"Mercury fluxes from hydrothermal venting at mid-ocean ridges constrained by measurements","AuthorsString":"Torres-Rodriguez, N. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":282627,"RR":"<b>Bourke, M.F.; Marriott, P.J.; Glud, R.N.; Hasler-Sheetal, H.; Kamalanathan, M.; Beardall, J.; Greening, C.; Cook, P.L.M.</b> (2017). Metabolism in anoxic permeable sediments is dominated by eukaryotic dark fermentation. <i>Nature Geoscience 10(1)</i>: 30-35. <a href=\"http://dx.doi.org/10.1038/ngeo2843\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2843</a>","StandardTitle":"Metabolism in anoxic permeable sediments is dominated by eukaryotic dark fermentation","AuthorsString":"Bourke, M.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":289157,"RR":"<b>Moore, E.K.; Jelen, B.I.; Giovannelli, D.; Raanan, H.; Falkowski, P.G.</b> (2017). Metal availability and the expanding network of microbial metabolisms in the Archaean eon. <i>Nature Geoscience 10(9)</i>: 629-636. <a href=\"https://dx.doi.org/10.1038/ngeo3006\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3006</a>","StandardTitle":"Metal availability and the expanding network of microbial metabolisms in the Archaean eon","AuthorsString":"Moore, E.K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":371749,"RR":"<b>Johnson, J.E.</b> (2023). Metals for microbes in the ancient sea. <i>Nature Geoscience 16(12)</i>: 1078-1079. <a href=\"https://dx.doi.org/10.1038/s41561-023-01314-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01314-z</a>","StandardTitle":"Metals for microbes in the ancient sea","AuthorsString":"Johnson, J.E.","BibLvlCode":"AS"},{"BRefID":404832,"RR":"<b>Valentine, D.L.</b> (2024). Methane evades microbes. <i>Nature Geoscience 17(12)</i>: 1197-1198. <a href=\"https://dx.doi.org/10.1038/s41561-024-01599-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01599-8</a>","StandardTitle":"Methane evades microbes","AuthorsString":"Valentine, D.L.","BibLvlCode":"AS"},{"BRefID":350635,"RR":"<b>Kim, B.; Zhang, Y.G.</b> (2022). Methane hydrate dissociation across the Oligocene–Miocene boundary. <i>Nature Geoscience 15</i>: 203-209. <a href=\"https://dx.doi.org/10.1038/s41561-022-00895-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00895-5</a>","StandardTitle":"Methane hydrate dissociation across the Oligocene–Miocene boundary","AuthorsString":"Kim, B.; Zhang, Y.G.","BibLvlCode":"AS"},{"BRefID":404833,"RR":"<b>Lapham, L.L.; Lloyd, K.G.; Fossing, H.; Flury, S.; Jensen, J.B.; Alperin, M.J.; Rehder, G.; Holzhueter, W.; Ferdelman, T.; Jørgensen, B.B.</b> (2024). Methane leakage through the sulfate–methane transition zone of the Baltic seabed. <i>Nature Geoscience 17(12)</i>: 1277-1283. <a href=\"https://dx.doi.org/10.1038/s41561-024-01594-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01594-z</a>","StandardTitle":"Methane leakage through the sulfate–methane transition zone of the Baltic seabed","AuthorsString":"Lapham, L.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359501,"RR":"<b>Nisbet, E.G.</b> (2022). Methane’s unknowns better known. <i>Nature Geoscience 15(11)</i>: 861-862. <a href=\"https://dx.doi.org/10.1038/s41561-022-01049-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01049-3</a>","StandardTitle":"Methane’s unknowns better known","AuthorsString":"Nisbet, E.G.","BibLvlCode":"AS"},{"BRefID":309974,"RR":"<b>Wang, S.-J.; Rudnick, R.L.; Gaschnig, R.M.; Wang, H.; Wasylenki, L.E.</b> (2019). Methanogenesis sustained by sulfide weathering during the Great Oxidation Event. <i>Nature Geoscience 12(4)</i>: 296-300. <a href=\"https://dx.doi.org/10.1038/s41561-019-0320-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0320-z</a>","StandardTitle":"Methanogenesis sustained by sulfide weathering during the Great Oxidation Event","AuthorsString":"Wang, S.-J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":230787,"RR":"<b>Herndl, G.J.; Reinthaler, T.</b> (2013). Microbial control of the dark end of the biological pump. <i>Nature Geoscience 6(9)</i>: 718-724. <a href=\"http://dx.doi.org/10.1038/NGEO1921\" target=\"_blank\">dx.doi.org/10.1038/NGEO1921</a>","StandardTitle":"Microbial control of the dark end of the biological pump","AuthorsString":"Herndl, G.J.; Reinthaler, T.","BibLvlCode":"AS"},{"BRefID":296260,"RR":"<b>Shah Walter, S.R.; Jaekel, U.; Osterholz, H.; Fisher, A.T.; Huber, J.A.; Pearson, A.; Dittmar, T.; Girguis, P.R.</b> (2018). Microbial decomposition of marine dissolved organic matter in cool oceanic crust. <i>Nature Geoscience 11(5)</i>: 334-339. <a href=\"https://dx.doi.org/10.1038/s41561-018-0109-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0109-5</a>","StandardTitle":"Microbial decomposition of marine dissolved organic matter in cool oceanic crust","AuthorsString":"Shah Walter, S.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":287577,"RR":"<b>Michaud, A.B.; Dore, J.E.; Achberger, A.M.; Christner, B.C.; Mitchell, A.C.; Skidmore, M.L.; Vick-Majors, T.J.; Priscu, J.C.</b> (2017). Microbial oxidation as a methane sink beneath the West Antarctic Ice Sheet. <i>Nature Geoscience 10(8)</i>: 582-586. <a href=\"https://dx.doi.org/10.1038/ngeo2992\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2992</a>","StandardTitle":"Microbial oxidation as a methane sink beneath the West Antarctic Ice Sheet","AuthorsString":"Michaud, A.B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":216109,"RR":"<b>Javaux, E.</b> (2011). Microfossils from early Earth. <i>Nature Geoscience 4(10)</i>: 663-665. <a href=\"http://dx.doi.org/10.1038/ngeo1279\" target=\"_blank\">dx.doi.org/10.1038/ngeo1279</a>","StandardTitle":"Microfossils from early Earth","AuthorsString":"Javaux, E.","BibLvlCode":"AS"},{"BRefID":371745,"RR":"<b>Tostevin, R.; Ahmed, I.A.M.</b> (2023). Micronutrient availability in Precambrian oceans controlled by greenalite formation. <i>Nature Geoscience 16(12)</i>: 1188-1193. <a href=\"https://dx.doi.org/10.1038/s41561-023-01294-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01294-0</a>","StandardTitle":"Micronutrient availability in Precambrian oceans controlled by greenalite formation","AuthorsString":"Tostevin, R.; Ahmed, I.A.M.","BibLvlCode":"AS"},{"BRefID":294788,"RR":"<b>Hurley, R.; Woodward, J.; Rothwell, J.J.</b> (2018). Microplastic contamination of river beds significantly reduced by catchment-wide flooding. <i>Nature Geoscience 11(4)</i>: 251-257. <a href=\"https://dx.doi.org/10.1038/s41561-018-0080-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0080-1</a>","StandardTitle":"Microplastic contamination of river beds significantly reduced by catchment-wide flooding","AuthorsString":"Hurley, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":355461,"RR":"<b>Pontes, Gabriel M.; Taschetto, Andréa S.; Sen Gupta, Alex; Santoso, Agus; Wainer, Ilana; Haywood, Alan M.; Chan, Wing-Le; Abe-Ouchi, Ayako; Stepanek, Christian; Lohmann, Gerrit; Hunter, Stephen J.; Tindall, Julia C.; Chandler, Mark A.; Sohl, Linda E.; Peltier, W. Richard; Chandan, Deepak; Kamae, Youichi; Nisancioglu, Kerim H.; Zhang, Zhongshi; Contoux, Camille; Tan, Ning; Zhang, Qiong; Otto-Bliesner, Bette L.; Brady, Esther C.; Feng, Ran; von der Heydt, Anna S.; Baatsen, Michiel L. J.; Oldeman, Arthur M.</b> (2022). Mid-Pliocene El Niño/Southern Oscillation suppressed by Pacific intertropical convergence zone shift. <i>Nature Geoscience 15(9)</i>: 726-734. <a href=\"https://dx.doi.org/10.1038/s41561-022-00999-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00999-y</a>","StandardTitle":"Mid-Pliocene El Niño/Southern Oscillation suppressed by Pacific intertropical convergence zone shift","AuthorsString":"Pontes, Gabriel M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":393302,"RR":"<b>Amarathunga, U.; Rohling, E.J.; Grant, K.M.; Francke, A.; Latimer, J.; Klaebe, R.M.; Heslop, D.; Roberts, A.P.; Hutchinson, D.K.</b> (2024). Mid-Pliocene glaciation preceded by a 0.5-million-year North African humid period. <i>Nature Geoscience 17(7)</i>: 660-666. <a href=\"https://dx.doi.org/10.1038/s41561-024-01472-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01472-8</a>","StandardTitle":"Mid-Pliocene glaciation preceded by a 0.5-million-year North African humid period","AuthorsString":"Amarathunga, U. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":365656,"RR":"<b>Mitchell, R.N.; Kirscher, U.</b> (2023). Mid-Proterozoic day length stalled by tidal resonance. <i>Nature Geoscience 16(7)</i>: 567-569. <a href=\"https://dx.doi.org/10.1038/s41561-023-01202-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01202-6</a>","StandardTitle":"Mid-Proterozoic day length stalled by tidal resonance","AuthorsString":"Mitchell, R.N.; Kirscher, U.","BibLvlCode":"AS"},{"BRefID":351412,"RR":"<b>Yu, J.; Oppo, D.W.; Jin, Z.; Lacerra, M.; Ji, X.; Umling, N.E.; Lund, D.C.; McCave, N.; Menviel, L.; Shao, J.; Xu, C.</b> (2022). Millennial and centennial CO<sub>2</sub> release from the Southern Ocean during the last deglaciation. <i>Nature Geoscience 15(4)</i>: 293-299. <a href=\"https://dx.doi.org/10.1038/s41561-022-00910-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00910-9</a>","StandardTitle":"Millennial and centennial CO<sub>2</sub> release from the Southern Ocean during the last deglaciation","AuthorsString":"Yu, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":371809,"RR":"<b>Yu, J.; Anderson, R.F.; Jin, Z.D.; Ji, X.; Thornalley, D.J.R.; Wu, L.; Thouveny, N.; Cai, Y.; Tan, L.; Zhang, F.; Menviel, L.; Tian, J.; Xie, X.; Rohling, E.J.; McManus, J.F.</b> (2023). Millennial atmospheric CO<sub>2</sub> changes linked to ocean ventilation modes over past 150,000 years. <i>Nature Geoscience 16(12)</i>: 1166-1173. <a href=\"https://dx.doi.org/10.1038/s41561-023-01297-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01297-x</a>","StandardTitle":"Millennial atmospheric CO<sub>2</sub> changes linked to ocean ventilation modes over past 150,000 years","AuthorsString":"Yu, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":439202,"RR":"<b>Thresher, R.E.; Rintoul, S.R.; Fallon, S.J.; Richer de Forges, S.; Neil, H.; Trotter, J.A.; Proctor, C.; Tracey, D.M.</b> (2026). Millennial-scale Atlantic overturning circulation led by the Southern Ocean. <i>Nature Geoscience 19(5)</i>: 520-525. <a href=\"https://dx.doi.org/10.1038/s41561-026-01959-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01959-6</a>","StandardTitle":"Millennial-scale Atlantic overturning circulation led by the Southern Ocean","AuthorsString":"Thresher, R.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359510,"RR":"<b>Hébert, R.; Herzschuh, U.; Laepple, T.</b> (2022). Millennial-scale climate variability over land overprinted by ocean temperature fluctuations. <i>Nature Geoscience 15(11)</i>: 899-905. <a href=\"https://dx.doi.org/10.1038/s41561-022-01056-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01056-4</a>","StandardTitle":"Millennial-scale climate variability over land overprinted by ocean temperature fluctuations","AuthorsString":"Hébert, R.; Herzschuh, U.; Laepple, T.","BibLvlCode":"AS"},{"BRefID":289764,"RR":"<b>Loveley, M.R.; Marcantonio, F.; Wisler, M.M.; Hertzberg, J.E.; Schmidt, M.W.; Lyle, M.</b> (2017). Millennial-scale iron fertilization of the eastern equatorial Pacific over the past 100,000 years. <i>Nature Geoscience 10(10)</i>: 760-764. <a href=\"https://dx.doi.org/10.1038/ngeo3024\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3024</a>","StandardTitle":"Millennial-scale iron fertilization of the eastern equatorial Pacific over the past 100,000 years","AuthorsString":"Loveley, M.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359755,"RR":"<b>Buessecker, S.; Imanaka, H.; Ely, T.; Hu, R.; Romaniello, S.J.; Cadillo-Quiroz, H.</b> (2022). Mineral-catalysed formation of marine NO and N<sub>2</sub>O on the anoxic early Earth. <i>Nature Geoscience 15(12)</i>: 1056-1063. <a href=\"https://dx.doi.org/10.1038/s41561-022-01089-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01089-9</a>","StandardTitle":"Mineral-catalysed formation of marine NO and N<sub>2</sub>O on the anoxic early Earth","AuthorsString":"Buessecker, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":435870,"RR":"<b>Bayer, B.; Kitzinger, K.; Paul, N.L.; Albers, J.B.; Saito, M.A.; Wagner, M.; Carlson, C.A.; Santoro, A.E.</b> (2025). Minor contribution of ammonia oxidizers to inorganic carbon fixation in the ocean. <i>Nature Geoscience 18(11)</i>: 1144-1151. <a href=\"https://dx.doi.org/10.1038/s41561-025-01798-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01798-x</a>","StandardTitle":"Minor contribution of ammonia oxidizers to inorganic carbon fixation in the ocean","AuthorsString":"Bayer, B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":240070,"RR":"<b>Samuel, H.; King, S.D.</b> (2014). Mixing at mid-ocean ridges controlled by small-scale convection and plate motion. <i>Nature Geoscience 7(8)</i>: 602-605. <a href=\"http://dx.doi.org/10.1038/ngeo2208\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2208</a>","StandardTitle":"Mixing at mid-ocean ridges controlled by small-scale convection and plate motion","AuthorsString":"Samuel, H.; King, S.D.","BibLvlCode":"AS"},{"BRefID":306498,"RR":"<b>Kuna, V.M.; Nábelek, J.L.; Braunmiller, J.</b> (2019). Mode of slip and crust–mantle interaction at oceanic transform faults. <i>Nature Geoscience 12(2)</i>: 138-142. <a href=\"https://dx.doi.org/10.1038/s41561-018-0287-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0287-1</a>","StandardTitle":"Mode of slip and crust–mantle interaction at oceanic transform faults","AuthorsString":"Kuna, V.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":233939,"RR":"<b>Tripati, A.K.; Sahany, S.; Pittman, D.; Eagle, R.A.; Neelin, J.D.; Mitchell, J.L.; Beaufort, L.</b> (2014). Modern and glacial tropical snowlines controlled by sea surface temperature and atmospheric mixing. <i>Nature Geoscience 7(3)</i>: 205-209. <a href=\"http://dx.doi.org/10.1038/ngeo2082\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2082</a>","StandardTitle":"Modern and glacial tropical snowlines controlled by sea surface temperature and atmospheric mixing","AuthorsString":"Tripati, A.K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":244509,"RR":"<b>Swanner, E.D.; Mloszewska, A.M.; Cirpka, O.A.; Schoenberg, R.; Konhauser, K.O.; Kappler, A.</b> (2015). Modulation of oxygen production in Archaean oceans by episodes of Fe(II) toxicity. <i>Nature Geoscience 8(2)</i>: 126-130. <a href=\"http://dx.doi.org/10.1038/ngeo2327\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2327</a>","StandardTitle":"Modulation of oxygen production in Archaean oceans by episodes of Fe(II) toxicity","AuthorsString":"Swanner, E.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":330720,"RR":"<b>Mishra, V.; Ambika, A.K.; Asoka, A.; Aadhar, S.; Buzan, J.; Kumar, R.; Huber, M.</b> (2020). Moist heat stress extremes in India enhanced by irrigation. <i>Nature Geoscience 13(11)</i>: 722-728. <a href=\"https://dx.doi.org/10.1038/s41561-020-00650-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00650-8</a>","StandardTitle":"Moist heat stress extremes in India enhanced by irrigation","AuthorsString":"Mishra, V. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":327890,"RR":"<b>Lamb, M.P.; de Leeuw, J.; Fischer, W.W.; Moodie, A.J.; Venditti, J.G.; Nittrouer, J.A.; Haught, D.; Parker, G.</b> (2020). Mud in rivers transported as flocculated and suspended bed material. <i>Nature Geoscience 13(8)</i>: 566-570. <a href=\"https://dx.doi.org/10.1038/s41561-020-0602-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0602-5</a>","StandardTitle":"Mud in rivers transported as flocculated and suspended bed material","AuthorsString":"Lamb, M.P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":290668,"RR":"<b>Charette, M.A.</b> (2017). Muddying Greenland's meltwaters. <i>Nature Geoscience 10(11)</i>: 804-805. <a href=\"https://dx.doi.org/10.1038/ngeo3055\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3055</a>","StandardTitle":"Muddying Greenland's meltwaters","AuthorsString":"Charette, M.A.","BibLvlCode":"AS"},{"BRefID":404831,"RR":"<b>Walker, C.; Millstein, J.D.; Miles, B.W.J.; Cook, S.; Fraser, A.D.; Colliander, A.; Misra, S.; Trusel, L.D.; Adusumilli, S.; Roberts, C.; Fricker, H.A.</b> (2024). Multi-decadal collapse of East Antarctica’s Conger–Glenzer Ice Shelf. <i>Nature Geoscience 17(12)</i>: 1240-1248. <a href=\"https://dx.doi.org/10.1038/s41561-024-01582-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01582-3</a>","StandardTitle":"Multi-decadal collapse of East Antarctica’s Conger–Glenzer Ice Shelf","AuthorsString":"Walker, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":334824,"RR":"<b>Crosta, X.; Etourneau, J.; Orme, L.C.; Dalaiden, Q.; Campagne, P.; Swingedouw, D.; Goosse, H.; Massé, G.; Miettinen, A.; McKay, R.M.; Dunbar, R.B.; Escutia, C.; Ikehara, M.</b> (2021). Multi-decadal trends in Antarctic sea-ice extent driven by ENSO–SAM over the last 2,000 years. <i>Nature Geoscience 14(3)</i>: 156-160. <a href=\"https://dx.doi.org/10.1038/s41561-021-00697-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00697-1</a>","StandardTitle":"Multi-decadal trends in Antarctic sea-ice extent driven by ENSO–SAM over the last 2,000 years","AuthorsString":"Crosta, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":404837,"RR":"<b>Mogen, S.C.; Lovenduski, N.S.; Yeager, S.G.; Capotondi, A.; Jacox, M.G.; Bograd, S.; Di Lorenzo, E.; Hazen, E.L.; Pozo Buil, M.; Kim, W.; Rosenbloom, N.</b> (2024). Multi-month forecasts of marine heatwaves and ocean acidification extremes. <i>Nature Geoscience 17(12)</i>: 1261-1267. <a href=\"https://dx.doi.org/10.1038/s41561-024-01593-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01593-0</a>","StandardTitle":"Multi-month forecasts of marine heatwaves and ocean acidification extremes","AuthorsString":"Mogen, S.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":363734,"RR":"<b>Pöppelmeier, F.; Jeltsch-Thömmes, A.; Lippold, J.; Joos, F.; Stocker, T.F.</b> (2023). Multi-proxy constraints on Atlantic circulation dynamics since the last ice age. <i>Nature Geoscience 16(4)</i>: 349-356. <a href=\"https://dx.doi.org/10.1038/s41561-023-01140-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01140-3</a>","StandardTitle":"Multi-proxy constraints on Atlantic circulation dynamics since the last ice age","AuthorsString":"Pöppelmeier, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":438829,"RR":"<b>Tsuchida, K.; Kosaka, Y.; Minobe, S.</b> (2026). Multi-year La Niña–El Niño transition influenced Earth’s extreme energy uptake in 2022–2023. <i>Nature Geoscience 19(4)</i>: 432-438. <a href=\"https://dx.doi.org/10.1038/s41561-026-01921-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01921-6</a>","StandardTitle":"Multi-year La Niña–El Niño transition influenced Earth’s extreme energy uptake in 2022–2023","AuthorsString":"Tsuchida, K.; Kosaka, Y.; Minobe, S.","BibLvlCode":"AS"},{"BRefID":361178,"RR":"<b>Yang, Y.; Song, X.</b> (2023). Multidecadal variation of the Earth’s inner-core rotation. <i>Nature Geoscience 16(2)</i>: 182-187. <a href=\"https://dx.doi.org/10.1038/s41561-022-01112-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01112-z</a>","StandardTitle":"Multidecadal variation of the Earth’s inner-core rotation","AuthorsString":"Yang, Y.; Song, X.","BibLvlCode":"AS"},{"BRefID":325383,"RR":"<b>Schefuß, E.; Dupont, L.</b> (2020). Multiple drivers of Miocene C<sub>4</sub> ecosystem expansions. <i>Nature Geoscience 13(7)</i>: 463-464. <a href=\"https://dx.doi.org/10.1038/s41561-020-0590-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0590-5</a>","StandardTitle":"Multiple drivers of Miocene C<sub>4</sub> ecosystem expansions","AuthorsString":"Schefuß, E.; Dupont, L.","BibLvlCode":"AS"},{"BRefID":344774,"RR":"<b>Sirocko, F.; Martínez-Garcia, A.; Mudelsee, M.; Albert, J.; Britzius, S.; Christl, M.; Diehl, D.; Diensberg, B.; Friedrich, R.; Fuhrmann, F.; Muscheler, R.; Hamann, Y.; Schneider, R.; Schwibus, K.; Haug, G.H.</b> (2021). Muted multidecadal climate variability in central Europe during cold stadial periods. <i>Nature Geoscience 14(9)</i>: 651-658. <a href=\"https://dx.doi.org/10.1038/s41561-021-00786-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00786-1</a>","StandardTitle":"Muted multidecadal climate variability in central Europe during cold stadial periods","AuthorsString":"Sirocko, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":282626,"RR":"<b>Bristow, L.A.; Callbeck, C.M.; Larsen, M.; Altabet, M.A.; Dekaezemacker, J.; Forth, M.; Gauns, M.; Glud, R.N.; Kuypers, M.M.M.; Lavik, G.; Milucka, J.; Naqvi, S.WA.; Pratihary, A.; Revsbech, N.P.; Thamdrup, B.; Treusch, A.H.; Canfield, D.E.</b> (2017). N<sub>2</sub> production rates limited by nitrite availability in the Bay of Bengal oxygen minimum zone. <i>Nature Geoscience 10(1)</i>: 24-29. <a href=\"http://dx.doi.org/10.1038/ngeo2847\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2847</a>","StandardTitle":"N<sub>2</sub> production rates limited by nitrite availability in the Bay of Bengal oxygen minimum zone","AuthorsString":"Bristow, L.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392765,"RR":"<b>Rantanen, M.</b> (2024). Natural variability boosts Arctic warming. <i>Nature Geoscience 17(6)</i>: 485-486. <a href=\"https://dx.doi.org/10.1038/s41561-024-01458-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01458-6</a>","StandardTitle":"Natural variability boosts Arctic warming","AuthorsString":"Rantanen, M.","BibLvlCode":"AS"},{"BRefID":392278,"RR":"<b>Sproson, Adam D.; Yokoyama, Yusuke; Miyairi, Yosuke; Aze, Takahiro; Clementi, Vincent J.; Riechelson, Hailey; Bova, Samantha C.; Rosenthal, Yair; Childress, Laurel B.; Aiello, Ivano W.; Avila, Alejandro; Biggs, William; Charles, Christopher D.; Cheung, Anson H.; deLong, Kimberly; Dove, Isabel A.; Du, Xiaojing; Estes, Emily R.; Fuentes, Ursula; García-Lasanta, Cristina; Goldstein, Steven L.; Golub, Anna; Hagemann, Julia Rieke; Hatfield, Robert G.; Haynes, Laura L.; Hess, Anya V.; Irvali, Nil; Kiro, Yael; Monteagudo, Minda M.; Lambert, Jonathan E.; Li, Chen; Longo, William M.; McGrath, Sarah; Robinson, Rebecca S.; Sarao, John; Taylor, Shawn; Wright, James D.; Yu, Siyao M.; the Expedition 379T Scientists</b> (2024). Near-synchronous Northern Hemisphere and Patagonian Ice Sheet variation over the last glacial cycle. <i>Nature Geoscience 17(5)</i>: 450-457. <a href=\"https://dx.doi.org/10.1038/s41561-024-01436-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01436-y</a>","StandardTitle":"Near-synchronous Northern Hemisphere and Patagonian Ice Sheet variation over the last glacial cycle","AuthorsString":"Sproson, Adam D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359502,"RR":"<b>Joung, D.; Ruppel, C.; Southon, J.; Weber, T.S.; Kessler, J.D.</b> (2022). Negligible atmospheric release of methane from decomposing hydrates in mid-latitude oceans. <i>Nature Geoscience 15(11)</i>: 885-891. <a href=\"https://dx.doi.org/10.1038/s41561-022-01044-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01044-8</a>","StandardTitle":"Negligible atmospheric release of methane from decomposing hydrates in mid-latitude oceans","AuthorsString":"Joung, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":308741,"RR":"<b>Bogard, M.J.; Kuhn, C.D.; Johnston, S.E.; Striegl, R.G.; Holtgrieve, G.W.; Dornblaser, M.M.; Spencer, R.G.M.; Wickland, K.P.; Butman, D.E.</b> (2019). Negligible cycling of terrestrial carbon in many lakes of the arid circumpolar landscape. <i>Nature Geoscience 12(3)</i>: 180-185. <a href=\"https://dx.doi.org/10.1038/s41561-019-0299-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0299-5</a>","StandardTitle":"Negligible cycling of terrestrial carbon in many lakes of the arid circumpolar landscape","AuthorsString":"Bogard, M.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":253971,"RR":"<b>Fairchild, I.J.</b> (2016). Neoproterozoic glass-bleeding. <i>Nature Geoscience 9(3)</i>: 192-193. <a href=\"http://dx.doi.org/10.1038/ngeo2643\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2643</a>","StandardTitle":"Neoproterozoic glass-bleeding","AuthorsString":"Fairchild, I.J.","BibLvlCode":"AS"},{"BRefID":294787,"RR":"<b>Konrad, H.; Shepherd, A.; Gilbert, L.; Hogg, A.E.; McMillan, M.; Muir, A.; Slater, T.</b> (2018). Net retreat of Antarctic glacier grounding lines. <i>Nature Geoscience 11(4)</i>: 258-262. <a href=\"https://dx.doi.org/10.1038/s41561-018-0082-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0082-z</a>","StandardTitle":"Net retreat of Antarctic glacier grounding lines","AuthorsString":"Konrad, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291790,"RR":"<b>DeVries, T.</b> (2018). New directions for ocean nutrients. <i>Nature Geoscience 11(1)</i>: 15-16. <a href=\"https://dx.doi.org/10.1038/s41561-017-0042-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0042-z</a>","StandardTitle":"New directions for ocean nutrients","AuthorsString":"DeVries, T.","BibLvlCode":"AS"},{"BRefID":282622,"RR":"<b>Rao, A.</b> (2017). New pathways in the sand. <i>Nature Geoscience 10(1)</i>: 3-4. <a href=\"http://dx.doi.org/10.1038/ngeo2855\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2855</a>","StandardTitle":"New pathways in the sand","AuthorsString":"Rao, A.","BibLvlCode":"AS"},{"BRefID":436568,"RR":"<b>Sun, X.; McCoy, D.; Xu, L.; Buchanan, P.J.; Zakem, E.J.</b> (2025). Nitrite accumulation in marine oxygen minimum zones induced by microbial nitrite consumers. <i>Nature Geoscience 18(12)</i>: 1273-1278. <a href=\"https://dx.doi.org/10.1038/s41561-025-01849-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01849-3</a>","StandardTitle":"Nitrite accumulation in marine oxygen minimum zones induced by microbial nitrite consumers","AuthorsString":"Sun, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396652,"RR":"<b>Hoerstmann, C.; Aguiar-González, B.; Barrillon, S.; Carpaneto Bastos, C.; Grosso, O.; Pérez-Hernández, M.D.; Doglioli, A.M.; Petrenko, A.A.; Carracedo, L.I.; Benavides, M.</b> (2024). Nitrogen fixation in the North Atlantic supported by Gulf Stream eddy-borne diazotrophs. <i>Nature Geoscience 17(11)</i>: 1141-1147. <a href=\"https://dx.doi.org/10.1038/s41561-024-01567-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01567-2</a>","StandardTitle":"Nitrogen fixation in the North Atlantic supported by Gulf Stream eddy-borne diazotrophs","AuthorsString":"Hoerstmann, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":347576,"RR":"<b>Fripiat, F.; Martínez-Garcia, A.; Marconi, D.; Fawcett, S.E.; Kopf, S.H.; Luu, V.H.; Rafter, P.A.; Zhang, R.; Sigman, D.M.; Haug, G.H.</b> (2021). Nitrogen isotopic constraints on nutrient transport to the upper ocean. <i>Nature Geoscience 14(11)</i>: 855-861. <a href=\"https://dx.doi.org/10.1038/s41561-021-00836-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00836-8</a>","StandardTitle":"Nitrogen isotopic constraints on nutrient transport to the upper ocean","AuthorsString":"Fripiat, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":308732,"RR":"<b>Jacobel, A.W.; Anderson, R.F.; Winckler, G.; Costa, K.M.; Gottschalk, J.; Middleton, J.L.; Pavia, F.J.; Shoenfelt, E.M.; <br >Zhou, Y.</b> (2019). No evidence for equatorial Pacific dust fertilization. <i>Nature Geoscience 12(3)</i>: 154-155. <a href=\"https://dx.doi.org/10.1038/s41561-019-0304-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0304-z</a>","StandardTitle":"No evidence for equatorial Pacific dust fertilization","AuthorsString":"Jacobel, A.W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":321962,"RR":"<b>Sibert, E.C.; Zill, M.E.; Frigyik, E.T.; Norris, R.D.</b> (2020). No state change in pelagic fish production and biodiversity during the Eocene–Oligocene transition. <i>Nature Geoscience 13(3)</i>: 238-242. <a href=\"https://dx.doi.org/10.1038/s41561-020-0540-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0540-2</a>","StandardTitle":"No state change in pelagic fish production and biodiversity during the Eocene–Oligocene transition","AuthorsString":"Sibert, E.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":383523,"RR":"<b>Jenkins, W.J.; Seltzer, A.M.; Gebbie, G.; German, C.R.</b> (2024). Noble gas evidence of a millennial-scale deep North Pacific palaeo-barometric anomaly. <i>Nature Geoscience 17(2)</i>: 114-117. <a href=\"https://dx.doi.org/10.1038/s41561-023-01368-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01368-z</a>","StandardTitle":"Noble gas evidence of a millennial-scale deep North Pacific palaeo-barometric anomaly","AuthorsString":"Jenkins, W.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":332650,"RR":"<b>Mariotti, A.; Blard, P.-H.; Charreau, J.; Toucanne, S.; Jorry, S.J.; Molliex, S.; Bourlès, D.L.; Aumaître, G.; Keddadouche, K.</b> (2021). Nonlinear forcing of climate on mountain denudation during glaciations. <i>Nature Geoscience 14(1)</i>: 16-22. <a href=\"https://dx.doi.org/10.1038/s41561-020-00672-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00672-2</a>","StandardTitle":"Nonlinear forcing of climate on mountain denudation during glaciations","AuthorsString":"Mariotti, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":242735,"RR":"<b>Brown, E.L.; Lesher, C.E.</b> (2014). North Atlantic magmatism controlled by temperature, mantle composition and buoyancy. <i>Nature Geoscience 7(11)</i>: 820–824. <a href=\"http://dx.doi.org/10.1038/ngeo2264\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2264</a>","StandardTitle":"North Atlantic magmatism controlled by temperature, mantle composition and buoyancy","AuthorsString":"Brown, E.L.; Lesher, C.E.","BibLvlCode":"AS"},{"BRefID":260854,"RR":"<b>Gagen, M.H.; Zorita, E.; McCarroll, D.; Zahn, M.; Young, G.H.F.; Robertson, I.</b> (2016). North Atlantic summer storm tracks over Europe dominated by internal variability over the past millennium. <i>Nature Geoscience 9(8)</i>: 630-635. <a href=\"http://dx.doi.org/10.1038/ngeo2752\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2752</a>","StandardTitle":"North Atlantic summer storm tracks over Europe dominated by internal variability over the past millennium","AuthorsString":"Gagen, M.H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":411044,"RR":"<b>Todd, V.L.G.; Shanahan, T.M.; DiNezio, P.N.; Klavans, J.M.; Fawcett, P.J.; Anderson, R.S.; Jiménez-Moreno, G.; LeGrande, A.N.; Pausata, F.S.R.; Thompson, A.J.; Zhu, J.</b> (2025). North Pacific Ocean–atmosphere responses to Holocene and future warming drive southwest US drought. <i>Nature Geoscience 18(7)</i>: 646-652. <a href=\"https://dx.doi.org/10.1038/s41561-025-01726-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01726-z</a>","StandardTitle":"North Pacific Ocean–atmosphere responses to Holocene and future warming drive southwest US drought","AuthorsString":"Todd, V.L.G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":306502,"RR":"<b>Cape, M.R.; Straneo, F.; Beaird, N.; Bundy, R.M.; Charette, M.A.</b> (2019). Nutrient release to oceans from buoyancy-driven upwelling at Greenland tidewater glaciers. <i>Nature Geoscience 12(1)</i>: 34-39. <a href=\"https://dx.doi.org/10.1038/s41561-018-0268-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0268-4</a>","StandardTitle":"Nutrient release to oceans from buoyancy-driven upwelling at Greenland tidewater glaciers","AuthorsString":"Cape, M.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":408333,"RR":"<b>Bonan, D.B.; Thompson, A.F.; Schneider, T.; Zanna, L.; Armour, K.C.; Sun, S.</b> (2025). Observational constraints imply limited future Atlantic meridional overturning circulation weakening. <i>Nature Geoscience 18(6)</i>: 479-487. <a href=\"https://dx.doi.org/10.1038/s41561-025-01709-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01709-0</a>","StandardTitle":"Observational constraints imply limited future Atlantic meridional overturning circulation weakening","AuthorsString":"Bonan, D.B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396660,"RR":"<b>Koman, G.; Bower, A.S.; Holliday, N.P.; Furey, H.H.; Fu, Y.; Biló, T.C.</b> (2024). Observed decrease in Deep Western Boundary Current transport in subpolar North Atlantic. <i>Nature Geoscience 17(11)</i>: 1148-1153. <a href=\"https://dx.doi.org/10.1038/s41561-024-01555-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01555-6</a>","StandardTitle":"Observed decrease in Deep Western Boundary Current transport in subpolar North Atlantic","AuthorsString":"Koman, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":439200,"RR":"<b>Mikaloff-Fletcher, S.E.</b> (2026). Observing the Southern Ocean carbon cycle from the skies. <i>Nature Geoscience 19(5)</i>: 500-501. <a href=\"https://dx.doi.org/10.1038/s41561-026-01964-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01964-9</a>","StandardTitle":"Observing the Southern Ocean carbon cycle from the skies","AuthorsString":"Mikaloff-Fletcher, S.E.","BibLvlCode":"AS"},{"BRefID":245787,"RR":"<b>Greenbaum, J.S.; Blankenship, D.D.; Young, D.A.; Richter, T.G.; Roberts, J.L.; Aitken, A.R.A.; Legresy, B.; Schroeder, D.M.; Warner, R.C.; van Ommen, T.D.; Siegert, M.J.</b> (2015). Ocean access to a cavity beneath Totten Glacier in East Antarctica. <i>Nature Geoscience 8(4)</i>: 294–298. <a href=\"http://dx.doi.org/10.1038/ngeo2388\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2388</a>","StandardTitle":"Ocean access to a cavity beneath Totten Glacier in East Antarctica","AuthorsString":"Greenbaum, J.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":285913,"RR":"<b>Whitchurch, A.</b> (2017). Ocean and ore. <i>Nature Geoscience 10(6)</i>: 399-399. <a href=\"https://dx.doi.org/10.1038/ngeo2966\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2966</a>","StandardTitle":"Ocean and ore","AuthorsString":"Whitchurch, A.","BibLvlCode":"AS"},{"BRefID":356588,"RR":"<b>Levin, L.A.</b> (2022). Ocean commitment and controversy. <i>Nature Geoscience 15(10)</i>: 754-755. <a href=\"https://dx.doi.org/10.1038/s41561-022-01042-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01042-w</a>","StandardTitle":"Ocean commitment and controversy","AuthorsString":"Levin, L.A.","BibLvlCode":"AS"},{"BRefID":281760,"RR":"<b>Amon, R.M.W.</b> (2016). Ocean dissolved organics matter. <i>Nature Geoscience 9(12)</i>: 864-865. <a href=\"http://dx.doi.org/10.1038/ngeo2841\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2841</a>","StandardTitle":"Ocean dissolved organics matter","AuthorsString":"Amon, R.M.W.","BibLvlCode":"AS"},{"BRefID":404828,"RR":"<b>Lunt, D.J.; Zhu, J.; Wood, R.A.</b> (2024). Ocean drilling makes for more robust climate modelling of the future. <i>Nature Geoscience 17(12)</i>: 1185-1186. <a href=\"https://dx.doi.org/10.1038/s41561-024-01604-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01604-0</a>","StandardTitle":"Ocean drilling makes for more robust climate modelling of the future","AuthorsString":"Lunt, D.J.; Zhu, J.; Wood, R.A.","BibLvlCode":"AS"},{"BRefID":309970,"RR":"<b>Jackson, R.</b> (2019). Ocean fingerprints on glacier motion. <i>Nature Geoscience 12(4)</i>: 224-225. <a href=\"https://dx.doi.org/10.1038/s41561-019-0343-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0343-5</a>","StandardTitle":"Ocean fingerprints on glacier motion","AuthorsString":"Jackson, R.","BibLvlCode":"AS"},{"BRefID":366131,"RR":"<b>Li, S.; Liu, W.; Allen, R.J.; Shi, J.-R.; Li, L.</b> (2023). Ocean heat uptake and interbasin redistribution driven by anthropogenic aerosols and greenhouse gases. <i>Nature Geoscience 16(8)</i>: 695-703. <a href=\"https://dx.doi.org/10.1038/s41561-023-01219-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01219-x</a>","StandardTitle":"Ocean heat uptake and interbasin redistribution driven by anthropogenic aerosols and greenhouse gases","AuthorsString":"Li, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":281128,"RR":"<b>Santos, C.F.; Agardy, T.; Andrade, F.; Barange, M.; Crowder, L.B.; Ehler, C.N.; Orbach, M.K.; Rosa, R.</b> (2016). Ocean planning in a changing climate. <i>Nature Geoscience 9(10)</i>: 730-730. <a href=\"http://dx.doi.org/10.1038/ngeo2821\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2821</a>","StandardTitle":"Ocean planning in a changing climate","AuthorsString":"Santos, C.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":243948,"RR":"<b>Dick, H.J.B.; Zhou, H.</b> (2015). Ocean rises are products of variable mantle composition, temperature and focused melting. <i>Nature Geoscience 8(1)</i>: 68-74. <a href=\"http://dx.doi.org/10.1038/ngeo2318\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2318</a>","StandardTitle":"Ocean rises are products of variable mantle composition, temperature and focused melting","AuthorsString":"Dick, H.J.B.; Zhou, H.","BibLvlCode":"AS"},{"BRefID":436567,"RR":"<b>Poinelli, M.; Siegelman, L.; Nakayama, Y.</b> (2025). Ocean submesoscales as drivers of submarine melting within Antarctic ice cavities. <i>Nature Geoscience 18(12)</i>: 1209-1215. <a href=\"https://dx.doi.org/10.1038/s41561-025-01831-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01831-z</a>","StandardTitle":"Ocean submesoscales as drivers of submarine melting within Antarctic ice cavities","AuthorsString":"Poinelli, M.; Siegelman, L.; Nakayama, Y.","BibLvlCode":"AS"},{"BRefID":334827,"RR":"<b>Volk, O.; White, R.S.; Pilia, S.; Green, R.G.; Maclennan, J.; Rawlinson, N.</b> (2021). Oceanic crustal flow in Iceland observed using seismic anisotropy. <i>Nature Geoscience 14(3)</i>: 168-173. <a href=\"https://dx.doi.org/10.1038/s41561-021-00702-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00702-7</a>","StandardTitle":"Oceanic crustal flow in Iceland observed using seismic anisotropy","AuthorsString":"Volk, O. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":313848,"RR":"<b>Sager, W.W.; Huang, Y.; Tominaga, M.; Greene, J.A.; Nakanishi, M.; Zhang, J.</b> (2019). Oceanic plateau formation by seafloor spreading implied by Tamu Massif magnetic anomalies. <i>Nature Geoscience 12(8)</i>: 661-666. <a href=\"https://dx.doi.org/10.1038/s41561-019-0390-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0390-y</a>","StandardTitle":"Oceanic plateau formation by seafloor spreading implied by Tamu Massif magnetic anomalies","AuthorsString":"Sager, W.W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":341635,"RR":"<b>Kohli, A.; Wolfson-Schwehr, M.; Prigent, C.; Warren, J.M.</b> (2021). Oceanic transform fault seismicity and slip mode influenced by seawater infiltration. <i>Nature Geoscience 14(8)</i>: 606-611. <a href=\"https://dx.doi.org/10.1038/s41561-021-00778-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00778-1</a>","StandardTitle":"Oceanic transform fault seismicity and slip mode influenced by seawater infiltration","AuthorsString":"Kohli, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":259368,"RR":"<b>Luo, H.; Castelao, R.M.; Rennermalm, A.K.; Tedesco, M.; Bracco, A.; Yager, P.L.; Mote, T.L.</b> (2016). Oceanic transport of surface meltwater from the southern Greenland ice sheet. <i>Nature Geoscience 9(7)</i>: 528-532. <a href=\"http://dx.doi.org/10.1038/ngeo2708\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2708</a>","StandardTitle":"Oceanic transport of surface meltwater from the southern Greenland ice sheet","AuthorsString":"Luo, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":437765,"RR":"<b>Boscolo-Galazzo, F.; Taylor, V.E.; Galaasen, E.V.; Liebrand, D.; Gasson, E.; Dallanave, E.; Fernandez-Bremer, A.; Witkowski, J.; Bohaty, S.M.; Meckler, A.N.</b> (2026). Oligocene deep ocean oxygen isotope variations primarily driven by temperature. <i>Nature Geoscience 19(2)</i>: 209-215. <a href=\"https://dx.doi.org/10.1038/s41561-025-01878-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01878-y</a>","StandardTitle":"Oligocene deep ocean oxygen isotope variations primarily driven by temperature","AuthorsString":"Boscolo-Galazzo, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392770,"RR":"<b>Gamaleldien, H.; Wu, L.-G.; Olierook, H.K.H.; Kirkland, C.L.; Kirscher, U.; Li, Z.X.; Johnson, T.E.; Makin, S.; Li, Q.-L.; Jiang, Q.; Wilde, S.A.; Li, X.-H.</b> (2024). Onset of the Earth’s hydrological cycle four billion years ago or earlier. <i>Nature Geoscience 17(6)</i>: 560-565. <a href=\"https://dx.doi.org/10.1038/s41561-024-01450-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01450-0</a>","StandardTitle":"Onset of the Earth’s hydrological cycle four billion years ago or earlier","AuthorsString":"Gamaleldien, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":338976,"RR":"<b>Brean, J.; Dall’Osto, M.; Simó, R.; Shi, Z.; Beddows, D.C.S.; Harrison, R.M.</b> (2021). Open ocean and coastal new particle formation from sulfuric acid and amines around the Antarctic Peninsula. <i>Nature Geoscience 14(6)</i>: 383-388. <a href=\"https://dx.doi.org/10.1038/s41561-021-00751-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00751-y</a>","StandardTitle":"Open ocean and coastal new particle formation from sulfuric acid and amines around the Antarctic Peninsula","AuthorsString":"Brean, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":331727,"RR":"<b>Matthews, H.D.; Tokarska, K.B.; Nicholls, Z.R.J.; Rogelj, J.; Canadell, J.G.; Friedlingstein, P.; Frölicher, T.L.; Forster, P.M.; Gillett, N.P.; Ilyina, T.; Jackson, R.B.; Jones, C.D.; Koven, C.D.; Knutti, R.; MacDougall, A.H.; Meinshausen, M.; Mengis, N.; Séférian, R.; Zickfeld, K.</b> (2020). Opportunities and challenges in using remaining carbon budgets to guide climate policy. <i>Nature Geoscience 13(12)</i>: 769-779. <a href=\"https://dx.doi.org/10.1038/s41561-020-00663-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00663-3</a>","StandardTitle":"Opportunities and challenges in using remaining carbon budgets to guide climate policy","AuthorsString":"Matthews, H.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":312360,"RR":"<b>Chemke, R.; Polvani, L.M.</b> (2019). Opposite tropical circulation trends in climate models and in reanalyses. <i>Nature Geoscience 12(7)</i>: 528-532. <a href=\"https://dx.doi.org/10.1038/s41561-019-0383-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0383-x</a>","StandardTitle":"Opposite tropical circulation trends in climate models and in reanalyses","AuthorsString":"Chemke, R.; Polvani, L.M.","BibLvlCode":"AS"},{"BRefID":241874,"RR":"<b>Nardin, W.; Edmonds, D.A.</b> (2014). Optimum vegetation height and density for inorganic sedimentation in deltaic marshes. <i>Nature Geoscience 7(10)</i>: 722-726. <a href=\"http://dx.doi.org/10.1038/ngeo2233\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2233</a>","StandardTitle":"Optimum vegetation height and density for inorganic sedimentation in deltaic marshes","AuthorsString":"Nardin, W.; Edmonds, D.A.","BibLvlCode":"AS"},{"BRefID":356601,"RR":"<b>Osselin, F.; Soulaine, C.; Fauguerolles, C.; Gaucher, E.C.; Scaillet, B.; Pichavant, M.</b> (2022). Orange hydrogen is the new green. <i>Nature Geoscience 15(10)</i>: 765-769. <a href=\"https://dx.doi.org/10.1038/s41561-022-01043-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01043-9</a>","StandardTitle":"Orange hydrogen is the new green","AuthorsString":"Osselin, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291295,"RR":"<b>Stigall, A.L.</b> (2017). Ordovician oxygen and biodiversity. <i>Nature Geoscience 10(12)</i>: 887-888. <a href=\"https://dx.doi.org/10.1038/s41561-017-0024-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0024-1</a>","StandardTitle":"Ordovician oxygen and biodiversity","AuthorsString":"Stigall, A.L.","BibLvlCode":"AS"},{"BRefID":438825,"RR":"<b>Stubbins, A.</b> (2026). Organic pollution found oceanwide. <i>Nature Geoscience 19(4)</i>: 362-363. <a href=\"https://dx.doi.org/10.1038/s41561-026-01958-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01958-7</a>","StandardTitle":"Organic pollution found oceanwide","AuthorsString":"Stubbins, A.","BibLvlCode":"AS"},{"BRefID":211512,"RR":"<b>Hoernle, K.; Hauff, F.; van den Bogaard, P.; Gibbons, A.D.; Conrad, S.; Müller, R.D.</b> (2011). Origin of Indian Ocean Seamount Province by shallow recycling of continental lithosphere. <i>Nature Geoscience 4(12)</i>: 883-887. <a href=\"http://dx.doi.org/10.1038/ngeo1331\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1331</a>","StandardTitle":"Origin of Indian Ocean Seamount Province by shallow recycling of continental lithosphere","AuthorsString":"Hoernle, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":287585,"RR":"<b>Margreth, A.</b> (2017). Origins of low-relief plateaus. <i>Nature Geoscience 10(8)</i>: 541-542. <a href=\"https://dx.doi.org/10.1038/ngeo2991\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2991</a>","StandardTitle":"Origins of low-relief plateaus","AuthorsString":"Margreth, A.","BibLvlCode":"AS"},{"BRefID":408001,"RR":"<b>Kasting, J.</b> (2025). Oscillating Archean oxygen oases. <i>Nature Geoscience 18(5)</i>: 372-373. <a href=\"https://dx.doi.org/10.1038/s41561-025-01690-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01690-8</a>","StandardTitle":"Oscillating Archean oxygen oases","AuthorsString":"Kasting, J.","BibLvlCode":"AS"},{"BRefID":414035,"RR":"<b> </b> (2025). Outburst of a subglacial flood from the surface of the Greenland Ice Sheet. <i>Nature Geoscience 18(8)</i>: 740-746. <a href=\"https://dx.doi.org/10.1038/s41561-025-01746-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01746-9</a>","StandardTitle":"Outburst of a subglacial flood from the surface of the Greenland Ice Sheet","AuthorsString":" ","BibLvlCode":"AS"},{"BRefID":365655,"RR":"<b>Giomi, F.; Barausse, A.; Steckbauer, A.; Daffonchio, D.; Duarte, C; Fusi, M.</b> (2023). Oxygen dynamics in marine productive ecosystems at ecologically relevant scales. <i>Nature Geoscience 16(7)</i>: 560-566. <a href=\"https://dx.doi.org/10.1038/s41561-023-01217-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01217-z</a>","StandardTitle":"Oxygen dynamics in marine productive ecosystems at ecologically relevant scales","AuthorsString":"Giomi, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":360446,"RR":"<b>Noyce, G.L.; Smith, A.J.; Kirwan, M.L.; Rich, R.L.; Megonigal, J.P.</b> (2023). Oxygen priming induced by elevated CO<sub>2</sub> reduces carbon accumulation and methane emissions in coastal wetlands. <i>Nature Geoscience 16(1)</i>: 63-68. <a href=\"https://dx.doi.org/10.1038/s41561-022-01070-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01070-6</a>","StandardTitle":"Oxygen priming induced by elevated CO<sub>2</sub> reduces carbon accumulation and methane emissions in coastal wetlands","AuthorsString":"Noyce, G.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":364403,"RR":"<b>Gaillard, F.</b> (2023). Oxygen-rich melt in deep magma oceans. <i>Nature Geoscience 16(5)</i>: 392-393. <a href=\"https://dx.doi.org/10.1038/s41561-023-01178-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01178-3</a>","StandardTitle":"Oxygen-rich melt in deep magma oceans","AuthorsString":"Gaillard, F.","BibLvlCode":"AS"},{"BRefID":368755,"RR":"<b>Wang, H.; Liu, W.; Lu, H.; Zhang, Y.; Liang, Y.; He, Y.; Bohaty, S.M.; Wilson, P.A.; Liu, Z.</b> (2023). Oxygenated deep waters fed early Atlantic overturning circulation upon Antarctic glaciation. <i>Nature Geoscience 16(11)</i>: 1014-1019. <a href=\"https://dx.doi.org/10.1038/s41561-023-01292-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01292-2</a>","StandardTitle":"Oxygenated deep waters fed early Atlantic overturning circulation upon Antarctic glaciation","AuthorsString":"Wang, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291300,"RR":"<b>Edwards, C.T.; Saltzman, M.R.; Royer, D.L.; Fike, D.A.</b> (2017). Oxygenation as a driver of the Great Ordovician Biodiversification Event. <i>Nature Geoscience 10(12)</i>: 925-929. <a href=\"https://dx.doi.org/10.1038/s41561-017-0006-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0006-3</a>","StandardTitle":"Oxygenation as a driver of the Great Ordovician Biodiversification Event","AuthorsString":"Edwards, C.T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":289757,"RR":"<b>Hoffmann, J.E.</b> (2017). Oxygenation by a changing crust. <i>Nature Geoscience 10(10)</i>: 713-714. <a href=\"https://dx.doi.org/10.1038/ngeo3038\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3038</a>","StandardTitle":"Oxygenation by a changing crust","AuthorsString":"Hoffmann, J.E.","BibLvlCode":"AS"},{"BRefID":368760,"RR":"<b>Lindskog, A.; Young, S.A.; Bowman, C.N.; Kozik, N.P.; Newby, S.M.; Eriksson, M.E.; Pettersson, J.; Molin, E.; Owens, J.D.</b> (2023). Oxygenation of the Baltoscandian shelf linked to Ordovician biodiversification. <i>Nature Geoscience 16(11)</i>: 1047-1053. <a href=\"https://dx.doi.org/10.1038/s41561-023-01287-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01287-z</a>","StandardTitle":"Oxygenation of the Baltoscandian shelf linked to Ordovician biodiversification","AuthorsString":"Lindskog, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":363320,"RR":"<b>Zhao, M.; Mills, B.J.W.; Homoky, W.B.; Peacock, C.L.</b> (2023). Oxygenation of the Earth aided by mineral–organic carbon preservation. <i>Nature Geoscience 16(3)</i>: 262-267. <a href=\"https://dx.doi.org/10.1038/s41561-023-01133-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01133-2</a>","StandardTitle":"Oxygenation of the Earth aided by mineral–organic carbon preservation","AuthorsString":"Zhao, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296267,"RR":"<b>Zhang, K.; Zhu, X.; Wood, R.A.; Shi, Y.; Gao, Z.; Poulton, S.W.</b> (2018). Oxygenation of the Mesoproterozoic ocean and the evolution of complex eukaryotes. <i>Nature Geoscience 11(5)</i>: 345-350. <a href=\"https://dx.doi.org/10.1038/s41561-018-0111-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0111-y</a>","StandardTitle":"Oxygenation of the Mesoproterozoic ocean and the evolution of complex eukaryotes","AuthorsString":"Zhang, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":353949,"RR":"(2022). Ozone depletion over the Arctic affects spring climate in the Northern Hemisphere. <i>Nature Geoscience 15(7)</i>: 518-519. <a href=\"https://dx.doi.org/10.1038/s41561-022-00983-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00983-6</a>","StandardTitle":"Ozone depletion over the Arctic affects spring climate in the Northern Hemisphere","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":217873,"RR":"<b>Jaccard, S.L.</b> (2012). Pacific and Atlantic synchronized. <i>Nature Geoscience 5(9)</i>: 594-596. <a href=\"http://dx.doi.org/10.1038/ngeo1563\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1563</a>","StandardTitle":"Pacific and Atlantic synchronized","AuthorsString":"Jaccard, S.L.","BibLvlCode":"AS"},{"BRefID":281766,"RR":"<b>Walker, B.D.; Beaupré, S.R.; Guilderson, T.P.; McCarthy, M.D.; Druffel, R.M.</b> (2016). Pacific carbon cycling constrained by organic matter size, age and composition relationships. <i>Nature Geoscience 9(12)</i>: 888-891. <a href=\"http://dx.doi.org/10.1038/ngeo2830\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2830</a>","StandardTitle":"Pacific carbon cycling constrained by organic matter size, age and composition relationships","AuthorsString":"Walker, B.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":247385,"RR":"<b>Lee, S.-K.; Park, W.; Baringer, M.O.; Gordon, A.L.; Huber, B.; Liu, Y.</b> (2015). Pacific origin of the abrupt increase in Indian Ocean heat content during the warming hiatus. <i>Nature Geoscience 8(6)</i>: 445–449. <a href=\"http://dx.doi.org/10.1038/ngeo2438\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2438</a>","StandardTitle":"Pacific origin of the abrupt increase in Indian Ocean heat content during the warming hiatus","AuthorsString":"Lee, S.-K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":329213,"RR":"<b>Haley, B.A.</b> (2020). Pacific push into the Atlantic. <i>Nature Geoscience 13(9)</i>: 595-596. <a href=\"https://dx.doi.org/10.1038/s41561-020-0626-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0626-x</a>","StandardTitle":"Pacific push into the Atlantic","AuthorsString":"Haley, B.A.","BibLvlCode":"AS"},{"BRefID":361137,"RR":"<b>Vos, K.; Harley, M.D.; Turner, I.L.; Splinter, K.D.</b> (2023). Pacific shoreline erosion and accretion patterns controlled by El Niño/Southern Oscillation. <i>Nature Geoscience 16(2)</i>: 140-146. <a href=\"https://dx.doi.org/10.1038/s41561-022-01117-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01117-8</a>","StandardTitle":"Pacific shoreline erosion and accretion patterns controlled by El Niño/Southern Oscillation","AuthorsString":"Vos, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":313850,"RR":"<b>Wang, C.; Song, S.; Wei, C.; Su, L.; Allen, M.B.; Niu, Y.; Li, X.-H.; Dong, J.</b> (2019). Palaeoarchaean deep mantle heterogeneity recorded by enriched plume remnants. <i>Nature Geoscience 12(8)</i>: 672-678. <a href=\"https://dx.doi.org/10.1038/s41561-019-0410-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0410-y</a>","StandardTitle":"Palaeoarchaean deep mantle heterogeneity recorded by enriched plume remnants","AuthorsString":"Wang, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":306503,"RR":"<b>Lyons, S.L.; Baczynski, A.A.; Babila, T.L.; Bralower, T.J.; Hajek, E.A.; Kump, L.R.; Polites, E.G.; Self-Trail, J.M.; Trampush, S.M.; Vornlocher, J.R.; Zachos, J.C.; Freeman, K.H.</b> (2019). Palaeocene–Eocene Thermal Maximum prolonged by fossil carbon oxidation. <i>Nature Geoscience 12(1)</i>: 54-60. <a href=\"https://dx.doi.org/10.1038/s41561-018-0277-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0277-3</a>","StandardTitle":"Palaeocene–Eocene Thermal Maximum prolonged by fossil carbon oxidation","AuthorsString":"Lyons, S.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":298380,"RR":"<b>Fischer, H.; Meissner, K.J.; Mix, A.C.; Abram, N.J.; Austermann, J.; Brovkin, V.; Capron, E.; Colombaroli, D.; Daniau, A.-L.; Dyez, K.A.; Felis, T.; Finkelstein, S.A.; Jaccard, S.L.; McClymont, E.L.; Rovere, A.; Sutter, J.; Wolff, E.W.; Affolter, S.; Bakker, P.; Ballesteros-Cánovas, J.A.; Barbante, C.; Caley, T.; Carlson, A.E.; Churakova, O.; Cortese, G.; Cumming, B.F.; Davis, B.A.S.; de Vernal, A.; Emile-Geay, J.; Fritz, S.C.; Gierz, P.; Gottschalk, J.; Holloway, M.D.; Joos, F.; Kucera, M.; Loutre, M.-F.; Lunt, D.J.; Marcisz, K.; Marlon, J.R.; Martinez, P.; Masson-Delmotte, V.; Nehrbass-Ahles, C.; Otto-Bliesner, B.L.; Raible, C.C.; Risebrobakken, B.; Sanchez Goñi, M.F.; Arrigo, J.S.; Sarnthein, M.; Sjolte, J.; Stocker, T.F.; Velasquez Alvárez, P.A.; Tinner, W.; Valdes, P.J.; Vogel, H.; Wanner, H.; Yan, Q.; Yu, Z.; Ziegler, M.; Zhou, L.</b> (2018). Palaeoclimate constraints on the impact of 2 °C anthropogenic warming and beyond. <i>Nature Geoscience 11(7)</i>: 474-485. <a href=\"https://dx.doi.org/10.1038/s41561-018-0146-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0146-0</a>","StandardTitle":"Palaeoclimate constraints on the impact of 2 °C anthropogenic warming and beyond","AuthorsString":"Fischer, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":245743,"RR":"<b>Newton, A.</b> (2015). Palaeoclimate: Maritime cooling. <i>Nature Geoscience 8(4)</i>: 259. <a href=\"http://dx.doi.org/10.1038/ngeo2411\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2411</a>","StandardTitle":"Palaeoclimate: Maritime cooling","AuthorsString":"Newton, A.","BibLvlCode":"AS"},{"BRefID":323340,"RR":"<b>Mänd, K.; Lalonde, S.V.; Robbins, L.J.; Thoby, M.; Paiste, K.; Kreitsmann, T.; Paiste, P.; Reinhard, C.T.; Romashkin, A.E.; Planavsky, N.J.; Kirsimäe, K.; Lepland, A.; Konhauser, K.O.</b> (2020). Palaeoproterozoic oxygenated oceans following the Lomagundi–Jatuli Event. <i>Nature Geoscience 13(4)</i>: 302-306. <a href=\"https://dx.doi.org/10.1038/s41561-020-0558-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0558-5</a>","StandardTitle":"Palaeoproterozoic oxygenated oceans following the Lomagundi–Jatuli Event","AuthorsString":"Mänd, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":261252,"RR":"<b>Granot, R.</b> (2016). Palaeozoic oceanic crust preserved beneath the eastern Mediterranean. <i>Nature Geoscience 9(9)</i>: 701-705. <a href=\"http://dx.doi.org/10.1038/ngeo2784\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2784</a>","StandardTitle":"Palaeozoic oceanic crust preserved beneath the eastern Mediterranean","AuthorsString":"Granot, R.","BibLvlCode":"AS"},{"BRefID":259363,"RR":"<b>Renault, L.; Deutsch, C.; McWilliams, J.C.; Frenzel, H.; Liang, J.-H.; Colas, F.</b> (2016). Partial decoupling of primary productivity from upwelling in the California Current system. <i>Nature Geoscience 9(7)</i>: 505-508. <a href=\"http://dx.doi.org/10.1038/ngeo2722\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2722</a>","StandardTitle":"Partial decoupling of primary productivity from upwelling in the California Current system","AuthorsString":"Renault, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":408330,"RR":"<b>Tyne, R.L.; Broadley, M.W.; Bekaert, D.V.; Barry, P.H.; Warr, O.; Langman, J.B.; Musan, I.; Jenkins, W.J.; Seltzer, A.M.</b> (2025). Passive degassing of lithospheric volatiles recorded in shallow young groundwater. <i>Nature Geoscience 18(6)</i>: 542-547. <a href=\"https://dx.doi.org/10.1038/s41561-025-01702-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01702-7</a>","StandardTitle":"Passive degassing of lithospheric volatiles recorded in shallow young groundwater","AuthorsString":"Tyne, R.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":341609,"RR":"<b>Brovkin, V.; Brook, E.; Williams, J.W.; Bathiany, S.; Lenton, T.M.; Barton, M.; DeConto, R.; Donges, J.F.; Ganopolski, A.; McManus, J.; Praetorius, S.; de Vernal, A.; Abe-Ouchi, A.; Cheng, H.; Claussen, M.; Crucifix, M.; Gallopín, G.; Iglesias, V.; Kaufman, D.S.; Kleinen, T.; Lambert, F.; Van der Leeuw, S.; Liddy, H.; Loutre, M.-F.; McGee, D.; Rehfeld, K.; Rhodes, R.; Seddon, A.W.R.; Trauth, M.H.; Vanderveken, L.; Yu, Z.</b> (2021). Past abrupt changes, tipping points and cascading impacts in the Earth system. <i>Nature Geoscience 14(8)</i>: 550-558. <a href=\"https://dx.doi.org/10.1038/s41561-021-00790-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00790-5</a>","StandardTitle":"Past abrupt changes, tipping points and cascading impacts in the Earth system","AuthorsString":"Brovkin, V. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":393309,"RR":"<b>Deitrick, R.; Goldblatt, C.</b> (2024). Past Earth warmed by tidal resonance-induced organization of clouds under a shorter day. <i>Nature Geoscience 17(7)</i>: 675-682. <a href=\"https://dx.doi.org/10.1038/s41561-024-01469-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01469-3</a>","StandardTitle":"Past Earth warmed by tidal resonance-induced organization of clouds under a shorter day","AuthorsString":"Deitrick, R.; Goldblatt, C.","BibLvlCode":"AS"},{"BRefID":406045,"RR":"<b>Brönnimann, S.; Franke, J.; Valler, V.; Hand, R.; Samakinwa, E.; Lundstad, E.; Burgdorf, A.-M.; Lipfert, L.; Pfister, L.; Imfeld, N.; Rohrer, M.</b> (2025). Past hydroclimate extremes in Europe driven by Atlantic jet stream and recurrent weather patterns. <i>Nature Geoscience 18(3)</i>: 246-253. <a href=\"https://dx.doi.org/10.1038/s41561-025-01654-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01654-y</a>","StandardTitle":"Past hydroclimate extremes in Europe driven by Atlantic jet stream and recurrent weather patterns","AuthorsString":"Brönnimann, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291302,"RR":"<b>Vannucchi, P.; Spagnuolo, E.; Aretusini, S.; Di Toro, G.; Ujiie, K.; Tsutsumi, A.; Nielsen, S.</b> (2017). Past seismic slip-to-the-trench recorded in Central America megathrust. <i>Nature Geoscience 10(12)</i>: 935-940. <a href=\"https://dx.doi.org/10.1038/s41561-017-0013-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0013-4</a>","StandardTitle":"Past seismic slip-to-the-trench recorded in Central America megathrust","AuthorsString":"Vannucchi, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":294038,"RR":"<b>Goodwin, P.; Katavouta, A.; Roussenov, V.M.; Foster, G.L.; Rohling, E.J.; Williams, R.G.</b> (2018). Pathways to 1.5 °C and 2 °C warming based on observational and geological constraints. <i>Nature Geoscience 11(2)</i>: 102-107. <a href=\"https://dx.doi.org/10.1038/s41561-017-0054-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0054-8</a>","StandardTitle":"Pathways to 1.5 °C and 2 °C warming based on observational and geological constraints","AuthorsString":"Goodwin, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":406043,"RR":"(2025). Pelagic calcifier proliferation along surface ocean gradients in carbonate chemistry. <i>Nature Geoscience 18(3)</i>: 205-206. <a href=\"https://dx.doi.org/10.1038/s41561-025-01646-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01646-y</a>","StandardTitle":"Pelagic calcifier proliferation along surface ocean gradients in carbonate chemistry","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":348083,"RR":"<b>Wassenburg, J.A.; Vonhof, H.B.; Cheng, H.; Martínez-Garcia, A.; Ebner, P.-R.; Li, X.; Zhang, H.; Sha, L.; Tian, Y.; Edwards, R.L.; Fiebig, J.; Haug, G.H.</b> (2021). Penultimate deglaciation Asian monsoon response to North Atlantic circulation collapse. <i>Nature Geoscience 14(12)</i>: 937-941. <a href=\"https://dx.doi.org/10.1038/s41561-021-00851-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00851-9</a>","StandardTitle":"Penultimate deglaciation Asian monsoon response to North Atlantic circulation collapse","AuthorsString":"Wassenburg, J.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":311225,"RR":"<b>Wallmann, K.; Flögel, S.; Scholz, F.; Dale, A. W.; Kemena, T.P.; Steinig, S.; Kuhnt, W.</b> (2019). Periodic changes in the Cretaceous ocean and climate caused by marine redox see-saw. <i>Nature Geoscience 12(6)</i>: 456-461. <a href=\"https://dx.doi.org/10.1038/s41561-019-0359-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0359-x</a>","StandardTitle":"Periodic changes in the Cretaceous ocean and climate caused by marine redox see-saw","AuthorsString":"Wallmann, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":437766,"RR":"<b>Li, Z.-H.; Chen, Z.-Q.; Daines, S.J.; Zhang, F.; Lenton, T.M.</b> (2026). Periodic ocean oxygenation events during the mid-Ediacaran. <i>Nature Geoscience 19(2)</i>: 216-222. <a href=\"https://dx.doi.org/10.1038/s41561-025-01883-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01883-1</a>","StandardTitle":"Periodic ocean oxygenation events during the mid-Ediacaran","AuthorsString":"Li, Z.-H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":336954,"RR":"<b>Matter, J.M.; Kelemen, P.</b> (2009). Permanent storage of carbon dioxide in geological reservoirs by mineral carbonation. <i>Nature Geoscience 2(12)</i>: 837-841. <a href=\"https://hdl.handle.net/10.1038/ngeo683\" target=\"_blank\">https://hdl.handle.net/10.1038/ngeo683</a>","StandardTitle":"Permanent storage of carbon dioxide in geological reservoirs by mineral carbonation","AuthorsString":"Matter, J.M.; Kelemen, P.","BibLvlCode":"AS"},{"BRefID":330725,"RR":"<b>Jurikova, H.; Gutjahr, M.; Wallmann, K.; Flögel, S.; Liebetrau, V.; Posenato, R.; Angiolini, L.; Garbelli, C.; Brand, U.; Wiedenbeck, M.; Eisenhauer, A.</b> (2020). Permian–Triassic mass extinction pulses driven by major marine carbon cycle perturbations. <i>Nature Geoscience 13(11)</i>: 745-750. <a href=\"https://dx.doi.org/10.1038/s41561-020-00646-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00646-4</a>","StandardTitle":"Permian–Triassic mass extinction pulses driven by major marine carbon cycle perturbations","AuthorsString":"Jurikova, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":356590,"RR":"<b>Cao, C.; Bataille, C.P.; Song, H.; Saltzman, M.R.; Tierney Cramer, K.; Wu, H.; Korte, C.; Zhang, Z.; Liu, X.-M.</b> (2022). Persistent late Permian to early Triassic warmth linked to enhanced reverse weathering. <i>Nature Geoscience 15(10)</i>: 832-838. <a href=\"https://dx.doi.org/10.1038/s41561-022-01009-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01009-x</a>","StandardTitle":"Persistent late Permian to early Triassic warmth linked to enhanced reverse weathering","AuthorsString":"Cao, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":347570,"RR":"<b>Sun, Y.; McManus, J.F.; Clemens, S.C.; Zhang, X.; Vogel, H.; Hodell, D.A.; Guo, F.; Wang, T.; Liu, X.; An, Z.</b> (2021). Persistent orbital influence on millennial climate variability through the Pleistocene. <i>Nature Geoscience 14(11)</i>: 812-818. <a href=\"https://dx.doi.org/10.1038/s41561-021-00794-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00794-1</a>","StandardTitle":"Persistent orbital influence on millennial climate variability through the Pleistocene","AuthorsString":"Sun, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":306496,"RR":"<b>Estes, E.; Pockalny, R.A.; D'Hondt, S.; Inagaki, F.; Morono, Y.; Murray, R.W.; Nordlund, D.; Spivack, A. J.; Wankel, S.D.; Xiao, N.; Hansel, C.M.</b> (2019). Persistent organic matter in oxic subseafloor sediment. <i>Nature Geoscience 12(2)</i>: 126-131. <a href=\"https://dx.doi.org/10.1038/s41561-018-0291-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0291-5</a>","StandardTitle":"Persistent organic matter in oxic subseafloor sediment","AuthorsString":"Estes, E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":303664,"RR":"<b>Fasullo, J.T.; Tilmes, S.; Richter, J.H.; Kravitz, B.; MacMartin, D.G.; Mills, M.J.; Simpson, I.R.</b> (2018). Persistent polar ocean warming in a strategically geoengineered climate. <i>Nature Geoscience 11(12)</i>: 910-914. <a href=\"https://dx.doi.org/10.1038/s41561-018-0249-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0249-7</a>","StandardTitle":"Persistent polar ocean warming in a strategically geoengineered climate","AuthorsString":"Fasullo, J.T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":330722,"RR":"<b>Chen, T.; Robinson, L.F.; Burke, A.; Claxton, L.M.; Hain, M.P.; Li, T.; Rae, J.W.B.; Stewart, J.; Knowles, T.D.J.; Fornari, D.J.; Harpp, K.S.</b> (2020). Persistently well-ventilated intermediate-depth ocean through the last deglaciation. <i>Nature Geoscience 13(11)</i>: 733-738. <a href=\"https://dx.doi.org/10.1038/s41561-020-0638-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0638-6</a>","StandardTitle":"Persistently well-ventilated intermediate-depth ocean through the last deglaciation","AuthorsString":"Chen, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":295271,"RR":"(2018). Pervasive plastic. <i>Nature Geoscience 11(5)</i>: 291-291. <a href=\"https://dx.doi.org/10.1038/s41561-018-0132-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0132-6</a>","StandardTitle":"Pervasive plastic","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":281759,"RR":"<b>Snow, J.E.</b> (2016). Petit spots go big. <i>Nature Geoscience 9(12)</i>: 862-863. <a href=\"http://dx.doi.org/10.1038/ngeo2839\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2839</a>","StandardTitle":"Petit spots go big","AuthorsString":"Snow, J.E.","BibLvlCode":"AS"},{"BRefID":338974,"RR":"<b>Duhamel, D.; Diaz, J.M.; Adams, J.C.; Djaoudi, K.; Steck, V.; Waggoner, E.M.</b> (2021). Phosphorus as an integral component of global marine biogeochemistry. <i>Nature Geoscience 14(6)</i>: 359-368. <a href=\"https://dx.doi.org/10.1038/s41561-021-00755-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00755-8</a>","StandardTitle":"Phosphorus as an integral component of global marine biogeochemistry","AuthorsString":"Duhamel, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":364412,"RR":"<b>Walton, C.R.; Ewens, S.; Coates, J.D.; Blake, R.E.; Planavsky, N.J.; Reinhard, C.; Ju, P.; Hao, J.; Pasek, M.A.</b> (2023). Phosphorus availability on the early Earth and the impacts of life. <i>Nature Geoscience 16(5)</i>: 399-409. <a href=\"https://dx.doi.org/10.1038/s41561-023-01167-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01167-6</a>","StandardTitle":"Phosphorus availability on the early Earth and the impacts of life","AuthorsString":"Walton, C.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":364402,"RR":"<b>Super, J.</b> (2023). Phosphorus from land to sea. <i>Nature Geoscience 16(5)</i>: 388-389. <a href=\"https://dx.doi.org/10.1038/s41561-023-01180-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01180-9</a>","StandardTitle":"Phosphorus from land to sea","AuthorsString":"Super, J.","BibLvlCode":"AS"},{"BRefID":323339,"RR":"<b>Guilbaud, R.; Poulton, S.W.; Thompson, J.; Husband, K.F.; Zhu, M.; Zhou, Y.; Shields, G.A.; Lenton, T.M.</b> (2020). Phosphorus-limited conditions in the early Neoproterozoic ocean maintained low levels of atmospheric oxygen. <i>Nature Geoscience 13(4)</i>: 296-301. <a href=\"https://dx.doi.org/10.1038/s41561-020-0548-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0548-7</a>","StandardTitle":"Phosphorus-limited conditions in the early Neoproterozoic ocean maintained low levels of atmospheric oxygen","AuthorsString":"Guilbaud, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":337179,"RR":"<b>Arnulf, A.F.; Biemiller, J.; Lavier, L.; Wallace, L.M.; Bassett, D.; Henrys, S.; Pecher, I.; Crutchley, G.; Plaza-Faverola, A.</b> (2021). Physical conditions and frictional properties in the source region of a slow-slip event. <i>Nature Geoscience 14(5)</i>: 334-340. <a href=\"https://hdl.handle.net/10.1038/s41561-021-00741-0\" target=\"_blank\">https://hdl.handle.net/10.1038/s41561-021-00741-0</a>","StandardTitle":"Physical conditions and frictional properties in the source region of a slow-slip event","AuthorsString":"Arnulf, A.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":253973,"RR":"<b>Behrenfeld, M.</b> (2016). Phytoplankton in a witch's brew. <i>Nature Geoscience 9(3)</i>: 194-195. <a href=\"http://dx.doi.org/10.1038/ngeo2644\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2644</a>","StandardTitle":"Phytoplankton in a witch's brew","AuthorsString":"Behrenfeld, M.","BibLvlCode":"AS"},{"BRefID":371765,"RR":"<b>Robinson, M.M.</b> (2023). Plankton reveal past climate. <i>Nature Geoscience 16(12)</i>: 1074-1075. <a href=\"https://dx.doi.org/10.1038/s41561-023-01343-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01343-8</a>","StandardTitle":"Plankton reveal past climate","AuthorsString":"Robinson, M.M.","BibLvlCode":"AS"},{"BRefID":355463,"RR":"<b>Greber, N.D.</b> (2022). Plant fingerprints in the deep Earth. <i>Nature Geoscience 15(9)</i>: 685–686. <a href=\"https://dx.doi.org/10.1038/s41561-022-01022-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01022-0</a>","StandardTitle":"Plant fingerprints in the deep Earth","AuthorsString":"Greber, N.D.","BibLvlCode":"AS"},{"BRefID":360445,"RR":"<b>O’Halloran, T.L.; Seyfried, G.S.</b> (2023). Plant traits and marsh fate. <i>Nature Geoscience 16(1)</i>: 4-5. <a href=\"https://dx.doi.org/10.1038/s41561-022-01108-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01108-9</a>","StandardTitle":"Plant traits and marsh fate","AuthorsString":"O’Halloran, T.L.; Seyfried, G.S.","BibLvlCode":"AS"},{"BRefID":325382,"RR":"<b>Carlson, R.W.</b> (2020). Plate tectonics from crust to core. <i>Nature Geoscience 13(7)</i>: 461-462. <a href=\"https://dx.doi.org/10.1038/s41561-020-0605-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0605-2</a>","StandardTitle":"Plate tectonics from crust to core","AuthorsString":"Carlson, R.W.","BibLvlCode":"AS"},{"BRefID":313841,"RR":"<b>Whittaker, J.M.</b> (2019). Plateaus from seafloor spreading. <i>Nature Geoscience 12(8)</i>: 587-588. <a href=\"https://dx.doi.org/10.1038/s41561-019-0416-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0416-5</a>","StandardTitle":"Plateaus from seafloor spreading","AuthorsString":"Whittaker, J.M.","BibLvlCode":"AS"},{"BRefID":405427,"RR":"<b>Llopis Monferrer, N.</b> (2025). Polar diatoms fade in the twilight zone. <i>Nature Geoscience 18(1)</i>: 5-6. <a href=\"https://dx.doi.org/10.1038/s41561-024-01620-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01620-0</a>","StandardTitle":"Polar diatoms fade in the twilight zone","AuthorsString":"Llopis Monferrer, N.","BibLvlCode":"AS"},{"BRefID":283196,"RR":"(2017). Polar merry-go-round. <i>Nature Geoscience 10(2)</i>: 74-75. <a href=\"http://dx.doi.org/10.1038/ngeo2870\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2870</a>","StandardTitle":"Polar merry-go-round","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":349083,"RR":"<b>Studholme, J.; Fedorov, A.V.; Gulev, S.K.; Emanuel, K.; Hodges, K.</b> (2022). Poleward expansion of tropical cyclone latitudes in warming climates. <i>Nature Geoscience 15(1)</i>: 14-28. <a href=\"https://dx.doi.org/10.1038/s41561-021-00859-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00859-1</a>","StandardTitle":"Poleward expansion of tropical cyclone latitudes in warming climates","AuthorsString":"Studholme, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":437130,"RR":"<b>Zhou, W.; Leung, L.R.; Chang, C.-C.; Zhao, M.; Hsu, H.-H.; Liang, H.-C.; Tu, C.-Y.; Balaguru, K.; Lu, J.</b> (2026). Poleward migration of tropical cyclones over 1980–2024 is dominated by Pacific variability. <i>Nature Geoscience 19(1)</i>: 42-51. <a href=\"https://dx.doi.org/10.1038/s41561-025-01866-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01866-2</a>","StandardTitle":"Poleward migration of tropical cyclones over 1980–2024 is dominated by Pacific variability","AuthorsString":"Zhou, W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396170,"RR":"<b>Chalif, J.I.; Jongebloed, U.A.; Osterberg, E.C.; Koffman, B.G.; Alexander, B.; Winski, D.A.; Polashenski, D.J.; Stamieszkin, K.; Ferris, D.G.; Kreutz, K.J.; Wake, C.P.; Cole-Dai, J.</b> (2024). Pollution drives multidecadal decline in subarctic methanesulfonic acid. <i>Nature Geoscience 17(10)</i>: 1016-1021. <a href=\"https://dx.doi.org/10.1038/s41561-024-01543-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01543-w</a>","StandardTitle":"Pollution drives multidecadal decline in subarctic methanesulfonic acid","AuthorsString":"Chalif, J.I. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":308737,"RR":"<b>Schneider, T.; Kaul, C.M.; Pressel, K.G.</b> (2019). Possible climate transitions from breakup of stratocumulus decks under greenhouse warming. <i>Nature Geoscience 12(3)</i>: 163-167. <a href=\"https://dx.doi.org/10.1038/s41561-019-0310-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0310-1</a>","StandardTitle":"Possible climate transitions from breakup of stratocumulus decks under greenhouse warming","AuthorsString":"Schneider, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":341615,"RR":"<b>Klatt, J.M.; Chennu, A.; Arbic, B.K.; Biddanda, B.A.; Dick, G.J.</b> (2021). Possible link between Earth’s rotation rate and oxygenation. <i>Nature Geoscience 14(8)</i>: 564-570. <a href=\"https://dx.doi.org/10.1038/s41561-021-00784-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00784-3</a>","StandardTitle":"Possible link between Earth’s rotation rate and oxygenation","AuthorsString":"Klatt, J.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":312028,"RR":"<b>He, T.; Zhu, M.; Mills, B.J.W.; Wynn, P.M.; Zhuravlev, A.Y.; Tostevin, R.; Pogge von Strandmann, P.A.E.; Yang, A.; Poulton, S.W.; Shields, G.A.</b> (2019). Possible links between extreme oxygen perturbations and the Cambrian radiation of animals. <i>Nature Geoscience 12(6)</i>: 468-474. <a href=\"https://dx.doi.org/10.1038/s41561-019-0357-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0357-z</a>","StandardTitle":"Possible links between extreme oxygen perturbations and the Cambrian radiation of animals","AuthorsString":"He, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":365663,"RR":"<b>Pilia, S.; Davies, D.R.; Hall, R.; Bacon, C.A.; Gilligan, A.; Greenfield, T.; Tongkul, F.; Kramer, S.C.; Wilson, C.R.; Ghelichkhan, S.; Cornwell, D.G.; Colli, L.; Rawlinson, N.</b> (2023). Post-subduction tectonics induced by extension from a lithospheric drip. <i>Nature Geoscience 16(7)</i>: 646-652. <a href=\"https://dx.doi.org/10.1038/s41561-023-01201-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01201-7</a>","StandardTitle":"Post-subduction tectonics induced by extension from a lithospheric drip","AuthorsString":"Pilia, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392772,"RR":"<b>Xing, K.-C.; Wang, F.; Teng, F.-Z.; Xu, W.-L.; Wang, Y.-N.; Yang, D.-B.; Li, H.-L.; Wang, Y.-C.</b> (2024). Potassium isotopic evidence for recycling of surface water into the mantle transition zone. <i>Nature Geoscience 17(6)</i>: 579-585. <a href=\"https://dx.doi.org/10.1038/s41561-024-01452-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01452-y</a>","StandardTitle":"Potassium isotopic evidence for recycling of surface water into the mantle transition zone","AuthorsString":"Xing, K.-C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291303,"RR":"<b>Brune, S.; Williams, S.E.; Müller, R.D.</b> (2017). Potential links between continental rifting, CO<sub>2</sub> degassing and climate change through time. <i>Nature Geoscience 10(12)</i>: 941-946. <a href=\"https://dx.doi.org/10.1038/s41561-017-0003-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0003-6</a>","StandardTitle":"Potential links between continental rifting, CO<sub>2</sub> degassing and climate change through time","AuthorsString":"Brune, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":338981,"RR":"<b>Gün, E.; Pysklywec, R.N.; Gögüs, O.H.; Topuz, G.</b> (2021). Pre-collisional extension of microcontinental terranes by a subduction pulley. <i>Nature Geoscience 14(6)</i>: 443-450. <a href=\"https://dx.doi.org/10.1038/s41561-021-00746-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00746-9</a>","StandardTitle":"Pre-collisional extension of microcontinental terranes by a subduction pulley","AuthorsString":"Gün, E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":281767,"RR":"<b>Pilet, S.; Abe, N.; Rochat, L.; Kaczmarek, M.-A.; Hirano, H.; Machida, S.; Buchs, D.M.; Baumgartner, P.O.; Müntener, O.</b> (2016). Pre-subduction metasomatic enrichment of the oceanic lithosphere induced by plate flexure. <i>Nature Geoscience 9(12)</i>: 898-903. <a href=\"http://dx.doi.org/10.1038/ngeo2825\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2825</a>","StandardTitle":"Pre-subduction metasomatic enrichment of the oceanic lithosphere induced by plate flexure","AuthorsString":"Pilet, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":436564,"RR":"<b>Balázs, A.; Gerya, T.; Tari, G.</b> (2025). Presence of continental slivers in oceanic transform faults determined by rift inheritance. <i>Nature Geoscience 18(12)</i>: 1303-1310. <a href=\"https://dx.doi.org/10.1038/s41561-025-01795-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01795-0</a>","StandardTitle":"Presence of continental slivers in oceanic transform faults determined by rift inheritance","AuthorsString":"Balázs, A.; Gerya, T.; Tari, G.","BibLvlCode":"AS"},{"BRefID":245580,"RR":"<b>D'Hondt, S.; Inagaki, F.; Alvarez Zarikian, C.A.; Abrams, L.J.; Dubois, N.; Engelhardt, T.; Evans, H.; Ferdelman, T.; Gribsholt, B.; Harris, R.N.; Hoppie, B.W.; Hyun, J.-H.; Kallmeyer, J.; Kim, J.; Lynch, J.E.; Mitsunobu, S.; Morono, Y.; Murray, R.W.; Shimono, T.; Shiraishi, F.; Smith, D.C.; Smith-Duque, C.E.; Spivack, A.J.; Steinsbu, B.O.; Suzuki, Y.; Szpak, M.; Toffin, L.; Uramoto, G.; Yamaguchi, Y.; Zhang, G.-l.; Zhang, X.-H.; Ziebis, W.</b> (2015). Presence of oxygen and aerobic communities from sea floor to basement in deep-sea sediments. <i>Nature Geoscience 8(4)</i>: 299–304. <a href=\"http://dx.doi.org/10.1038/ngeo2387\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2387</a>","StandardTitle":"Presence of oxygen and aerobic communities from sea floor to basement in deep-sea sediments","AuthorsString":"D'Hondt, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":405430,"RR":"<b>Babakhani, P.; Dale, A.W.; Woulds, C.; Moore, O.W.; Xiao, K.-Q.; Curti, L.; Peacock, C.L.</b> (2025). Preservation of organic carbon in marine sediments sustained by sorption and transformation processes. <i>Nature Geoscience 18(1)</i>: 78-83. <a href=\"https://dx.doi.org/10.1038/s41561-024-01606-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01606-y</a>","StandardTitle":"Preservation of organic carbon in marine sediments sustained by sorption and transformation processes","AuthorsString":"Babakhani, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":408008,"RR":"<b>Blaser, P.; Waelbroeck, C.; Thornalley, D.J.R.; Lippold, J.; Pöppelmeier, F.; Kaboth-Bahr, S.; Repschläger, J.; Jaccard, S.L.</b> (2025). Prevalent North Atlantic Deep Water during the Last Glacial Maximum and Heinrich Stadial 1. <i>Nature Geoscience 18(5)</i>: 410-416. <a href=\"https://dx.doi.org/10.1038/s41561-025-01685-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01685-5</a>","StandardTitle":"Prevalent North Atlantic Deep Water during the Last Glacial Maximum and Heinrich Stadial 1","AuthorsString":"Blaser, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":329785,"RR":"<b>Moore, C.M.; Mills, M.M.; Arrigo, K.R.; Berman-Frank, I.; Bopp, L.; Boyd, P.W.; Galbraith, E.D.; Geider, R.J.; Guieu, C.; Jaccard, S.L.; Jickells, T.D.; La Roche, J.; Lenton, T.M.; Mahowald, N.M.; Marañón, E.; Marinov, I.; Moore, J.K.; Nakatsuka, T.; Oschlies, A.; Saito, M.A.; Thingstad, T.F.; Tsuda, A.; Ulloa, O.</b> (2013). Processes and patterns of oceanic nutrient limitation. <i>Nature Geoscience 6(9)</i>: 701-710. <a href=\"https://dx.doi.org/10.1038/ngeo1765\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo1765</a>","StandardTitle":"Processes and patterns of oceanic nutrient limitation","AuthorsString":"Moore, C.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":391794,"RR":"<b>Gianchandani, K.; Halevy, I.; Gildor, H.; Ashkenazy, Y.; Tziperman, E.</b> (2024). Production of Neoproterozoic banded iron formations in a partially ice-covered ocean. <i>Nature Geoscience 17(4)</i>: 298-301. <a href=\"https://dx.doi.org/10.1038/s41561-024-01406-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01406-4</a>","StandardTitle":"Production of Neoproterozoic banded iron formations in a partially ice-covered ocean","AuthorsString":"Gianchandani, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":334819,"RR":"<b>Zhang, Y.; Held, I.; Fueglistaler, S.</b> (2021). Projections of tropical heat stress constrained by atmospheric dynamics. <i>Nature Geoscience 14(3)</i>: 133-137. <a href=\"https://dx.doi.org/10.1038/s41561-021-00695-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00695-3</a>","StandardTitle":"Projections of tropical heat stress constrained by atmospheric dynamics","AuthorsString":"Zhang, Y.; Held, I.; Fueglistaler, S.","BibLvlCode":"AS"},{"BRefID":310830,"RR":"<b>Fakhraee, M.; Hancisse, O.; Canfield, D.E.; Crowe, S.A.; Katsev, S.</b> (2019). Proterozoic seawater sulfate scarcity and the evolution of ocean–atmosphere chemistry. <i>Nature Geoscience 12(5)</i>: 375-380. <a href=\"https://dx.doi.org/10.1038/s41561-019-0351-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0351-5</a>","StandardTitle":"Proterozoic seawater sulfate scarcity and the evolution of ocean–atmosphere chemistry","AuthorsString":"Fakhraee, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296272,"RR":"<b>Spakman, W.; Chertova, M.V.; van den Berg, A.P.; Van Hinsbergen, D.J.J.</b> (2018). Publisher Correction: Puzzling features of western Mediterranean tectonics explained by slab dragging. <i>Nature Geoscience 11(5)</i>: 374-374. <a href=\"https://dx.doi.org/10.1038/s41561-018-0096-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0096-6</a>","StandardTitle":"Publisher Correction: Puzzling features of western Mediterranean tectonics explained by slab dragging","AuthorsString":"Spakman, W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296270,"RR":"<b>Zhou, Q.; Liu, L.; Hu, J.</b> (2018). Publisher Correction: Western US volcanism due to intruding oceanic mantle driven by ancient Farallon slabs. <i>Nature Geoscience 11(5)</i>: 374. <a href=\"https://dx.doi.org/10.1038/s41561-018-0062-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0062-3</a>","StandardTitle":"Publisher Correction: Western US volcanism due to intruding oceanic mantle driven by ancient Farallon slabs","AuthorsString":"Zhou, Q. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296257,"RR":"<b>Jaccard, S.L.; Galbraith, E.D.</b> (2018). Push from the Pacific. <i>Nature Geoscience 11(5)</i>: 299-300. <a href=\"https://dx.doi.org/10.1038/s41561-018-0119-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0119-3</a>","StandardTitle":"Push from the Pacific","AuthorsString":"Jaccard, S.L.; Galbraith, E.D.","BibLvlCode":"AS"},{"BRefID":363312,"RR":"<b>Röthlisberger, M.; Papritz, L.</b> (2023). Quantifying the physical processes leading to atmospheric hot extremes at a global scale. <i>Nature Geoscience 16(3)</i>: 210-216. <a href=\"https://dx.doi.org/10.1038/s41561-023-01126-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01126-1</a>","StandardTitle":"Quantifying the physical processes leading to atmospheric hot extremes at a global scale","AuthorsString":"Röthlisberger, M.; Papritz, L.","BibLvlCode":"AS"},{"BRefID":365659,"RR":"<b>Chen, T.; Robinson, L.F.; Li, T.; Burke, A.; Zhang, X.; Stewart, J.A.; White, N.J.; Knowles, T.D.J.</b> (2023). Radiocarbon evidence for the stability of polar ocean overturning during the Holocene. <i>Nature Geoscience 16(7)</i>: 631-636. <a href=\"https://dx.doi.org/10.1038/s41561-023-01214-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01214-2</a>","StandardTitle":"Radiocarbon evidence for the stability of polar ocean overturning during the Holocene","AuthorsString":"Chen, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":345735,"RR":"<b>Liljedahl, L.C.; Meierbachtol, T.; Harper, J.; van As, D.; Näslund, J.-O.; Selroos, J.-O.; Saito, J.; Follin, S.; Ruskeeniemi, T.; Kontula, A.; Humphrey, N.</b> (2021). Rapid and sensitive response of Greenland’s groundwater system to ice sheet change. <i>Nature Geoscience 14(10)</i>: 751-755. <a href=\"https://dx.doi.org/10.1038/s41561-021-00813-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00813-1</a>","StandardTitle":"Rapid and sensitive response of Greenland’s groundwater system to ice sheet change","AuthorsString":"Liljedahl, L.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":415788,"RR":"<b>Wong, K.; Morgan, D.; Ferguson, D.; Edmonds, M.; Tadesse, A.Z.; Murphy Quinlan, M.; Yirgu, G.; Wright, T.</b> (2025). Rapid crustal transit of magmas beneath the Main Ethiopian Rift. <i>Nature Geoscience 18(9)</i>: 916-922. <a href=\"https://dx.doi.org/10.1038/s41561-025-01770-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01770-9</a>","StandardTitle":"Rapid crustal transit of magmas beneath the Main Ethiopian Rift","AuthorsString":"Wong, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":339836,"RR":"<b>Eayrs, C.; Li, X.; Raphael, M.N.; Holland, D.M.</b> (2021). Rapid decline in Antarctic sea ice in recent years hints at future change. <i>Nature Geoscience 14(7)</i>: 460–464. <a href=\"https://dx.doi.org/10.1038/s41561-021-00768-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00768-3</a>","StandardTitle":"Rapid decline in Antarctic sea ice in recent years hints at future change","AuthorsString":"Eayrs, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":349089,"RR":"<b>Milillo, P.; Rignot, E.; Rizzoli, R.; Scheuchl, B.; Mouginot, J.; Bueso-Bello, J.L.; Prats-Iraola, P.; Dini, L.</b> (2022). Rapid glacier retreat rates observed in West Antarctica. <i>Nature Geoscience 15(1)</i>: 48-53. <a href=\"https://dx.doi.org/10.1038/s41561-021-00877-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00877-z</a>","StandardTitle":"Rapid glacier retreat rates observed in West Antarctica","AuthorsString":"Milillo, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":355458,"RR":"<b>Graham, A.G.C.; Wahlin, A.; Hogan, K.A.; Nitsche, F.O.; Heywood, K.J.; Totten, R.L.; Smith, J.A.; Hillenbrand, C.-D.; Simkins, L.M.; Anderson, J.B.; Wellner, J.S.; Larter, R.D.</b> (2022). Rapid retreat of Thwaites Glacier in the pre-satellite era. <i>Nature Geoscience 15(9)</i>: 706–713. <a href=\"https://dx.doi.org/10.1038/s41561-022-01019-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01019-9</a>","StandardTitle":"Rapid retreat of Thwaites Glacier in the pre-satellite era","AuthorsString":"Graham, A.G.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":405432,"RR":"<b>Jurikova, H.; Garbelli, C.; Whiteford, R.; Reeves, T.; Laker, G.M.; Liebetrau, V.; Gutjahr, M.; Eisenhauer, A.; Savickaite, K.; Leng, M.J.; Iurino, D.A.; Viaretti, M.; Tomasovych, A.; Zhang, Y.; Wang, W.; Shi, G.R.; Shen, S-z.; Rae, J.W.B.; Angiolini, L.</b> (2025). Rapid rise in atmospheric CO<sub>2</sub> marked the end of the Late Palaeozoic Ice Age. <i>Nature Geoscience 18(1)</i>: 91-97. <a href=\"https://dx.doi.org/10.1038/s41561-024-01610-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01610-2</a>","StandardTitle":"Rapid rise in atmospheric CO<sub>2</sub> marked the end of the Late Palaeozoic Ice Age","AuthorsString":"Jurikova, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":406047,"RR":"<b>Guo, M.; Korenaga, J.</b> (2025). Rapid rise of early ocean pH under elevated weathering rates. <i>Nature Geoscience 18(3)</i>: 260-266. <a href=\"https://dx.doi.org/10.1038/s41561-025-01649-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01649-9</a>","StandardTitle":"Rapid rise of early ocean pH under elevated weathering rates","AuthorsString":"Guo, M.; Korenaga, J.","BibLvlCode":"AS"},{"BRefID":241873,"RR":"<b>Rye, C.D.; Naveira Garabato, AC.; Holland, P.R.; Meredith, M.P.; Nurser, A.J.G.; Hughes, C.W.; Coward, A.C.; Webb, D.J.</b> (2014). Rapid sea-level rise along the Antarctic margins in response to increased glacial discharge. <i>Nature Geoscience 7(10)</i>: 732-735. <a href=\"http://dx.doi.org/10.1038/ngeo2230\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2230</a>","StandardTitle":"Rapid sea-level rise along the Antarctic margins in response to increased glacial discharge","AuthorsString":"Rye, C.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":312364,"RR":"<b>Mutch, E.J.F.; Maclennan, J.; Shorttle, O.; Edmonds, M.; Rudge, J.F.</b> (2019). Rapid transcrustal magma movement under Iceland. <i>Nature Geoscience 12(7)</i>: 569-574. <a href=\"https://dx.doi.org/10.1038/s41561-019-0376-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0376-9</a>","StandardTitle":"Rapid transcrustal magma movement under Iceland","AuthorsString":"Mutch, E.J.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":321960,"RR":"<b>Atamanchuk, D.; Koelling, J.; Send, U.; Wallace, D.W.R.</b> (2020). Rapid transfer of oxygen to the deep ocean mediated by bubbles. <i>Nature Geoscience 13(3)</i>: 232-237. <a href=\"https://dx.doi.org/10.1038/s41561-020-0532-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0532-2</a>","StandardTitle":"Rapid transfer of oxygen to the deep ocean mediated by bubbles","AuthorsString":"Atamanchuk, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":360457,"RR":"<b>Sharoni, S.; Halevy, I.</b> (2023). Rates of seafloor and continental weathering govern Phanerozoic marine phosphate levels. <i>Nature Geoscience 16(1)</i>: 75-81. <a href=\"https://dx.doi.org/10.1038/s41561-022-01075-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01075-1</a>","StandardTitle":"Rates of seafloor and continental weathering govern Phanerozoic marine phosphate levels","AuthorsString":"Sharoni, S.; Halevy, I.","BibLvlCode":"AS"},{"BRefID":298396,"RR":"<b>Lough, A.C.; Wiens, D.A.; Nyblade, A.</b> (2018). Reactivation of ancient Antarctic rift zones by intraplate seismicity. <i>Nature Geoscience 11(7)</i>: 515-519. <a href=\"https://dx.doi.org/10.1038/s41561-018-0140-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0140-6</a>","StandardTitle":"Reactivation of ancient Antarctic rift zones by intraplate seismicity","AuthorsString":"Lough, A.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366742,"RR":"<b>Kang, S.M.; Ceppi, P.; Yu, Y.; Kang, I.-S.</b> (2023). Recent global climate feedback controlled by Southern Ocean cooling. <i>Nature Geoscience 16(9)</i>: 775-780. <a href=\"https://dx.doi.org/10.1038/s41561-023-01256-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01256-6</a>","StandardTitle":"Recent global climate feedback controlled by Southern Ocean cooling","AuthorsString":"Kang, S.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":303724,"RR":"<b>Wang, J.; Song, C.; Reager, J.T.; Yao, F.; Famiglietti, J.S.; Sheng, Y.; MacDonald, G.M.; Brun, F.; Schmied, H.M.; Marston, R.A.; Wada, Y.</b> (2018). Recent global decline in endorheic basin water storages. <i>Nature Geoscience 11(12)</i>: 926-932. <a href=\"https://dx.doi.org/10.1038/s41561-018-0265-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0265-7</a>","StandardTitle":"Recent global decline in endorheic basin water storages","AuthorsString":"Wang, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":331728,"RR":"<b>Silvano, A.; Foppert, A.; Rintoul, S.R.; Holland, P.R.; Tamura, T.; Kimura, N.; Castagno, P.; Falco, P.; Budillon, G.; Haumann, F.A.; Naveira Garabato, A.C.; MacDonald, A.M.</b> (2020). Recent recovery of Antarctic Bottom Water formation in the Ross Sea driven by climate anomalies. <i>Nature Geoscience 13(12)</i>: 780-786. <a href=\"https://dx.doi.org/10.1038/s41561-020-00655-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00655-3</a>","StandardTitle":"Recent recovery of Antarctic Bottom Water formation in the Ross Sea driven by climate anomalies","AuthorsString":"Silvano, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":259366,"RR":"<b>Jackson, L.C.; Peterson, K.A.; Roberts, C.D.; Wood, R.A.</b> (2016). Recent slowing of Atlantic overturning circulation as a recovery from earlier strengthening. <i>Nature Geoscience 9(7)</i>: 518-522. <a href=\"http://dx.doi.org/10.1038/ngeo2715\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2715</a>","StandardTitle":"Recent slowing of Atlantic overturning circulation as a recovery from earlier strengthening","AuthorsString":"Jackson, L.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":302857,"RR":"<b>Swart, N.C.; Gille, S.T.; Fyfe, J.C.; Gillett, N.P.</b> (2018). Recent Southern Ocean warming and freshening driven by greenhouse gas emissions and ozone depletion. <i>Nature Geoscience 11(11)</i>: 836-841. <a href=\"https://dx.doi.org/10.1038/s41561-018-0226-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0226-1</a>","StandardTitle":"Recent Southern Ocean warming and freshening driven by greenhouse gas emissions and ozone depletion","AuthorsString":"Swart, N.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":411042,"RR":"<b>Kuo, Y.-N.; Lehner, F.; Simpson, I.R.; Deser, C.; Phillips, A.S.; Newman, M.; Shin, S.I.; Wong, S.; Arblaster, J.M.</b> (2025). Recent southwestern US drought exacerbated by anthropogenic aerosols and tropical ocean warming. <i>Nature Geoscience 18(7)</i>: 578-585. <a href=\"https://dx.doi.org/10.1038/s41561-025-01728-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01728-x</a>","StandardTitle":"Recent southwestern US drought exacerbated by anthropogenic aerosols and tropical ocean warming","AuthorsString":"Kuo, Y.-N. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":365452,"RR":"<b>Lin, P.; Pickart, R.S.; Heorton, H.; Tsamados, M.; Itoh, M.; Kikuchi, T.</b> (2023). Recent state transition of the Arctic Ocean’s Beaufort Gyre. <i>Nature Geoscience 16(6)</i>: 485-491. <a href=\"https://dx.doi.org/10.1038/s41561-023-01184-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01184-5</a>","StandardTitle":"Recent state transition of the Arctic Ocean’s Beaufort Gyre","AuthorsString":"Lin, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":347572,"RR":"<b>Riihelä, A.; Bright, R.M.; Anttila, K.</b> (2021). Recent strengthening of snow and ice albedo feedback driven by Antarctic sea-ice loss. <i>Nature Geoscience 14(11)</i>: 832-836. <a href=\"https://dx.doi.org/10.1038/s41561-021-00841-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00841-x</a>","StandardTitle":"Recent strengthening of snow and ice albedo feedback driven by Antarctic sea-ice loss","AuthorsString":"Riihelä, A.; Bright, R.M.; Anttila, K.","BibLvlCode":"AS"},{"BRefID":366506,"RR":"<b>Tank, Suzanne E.; McClelland, James W.; Spencer, Robert G. M.; Shiklomanov, Alexander I.; Suslova, Anya; Moatar, Florentina; Amon, Rainer M. W.; Cooper, Lee W.; Elias, Greg; Gordeev, Vyacheslav V.; Guay, Christopher; Gurtovaya, Tatiana Yu.; Kosmenko, Lyudmila S.; Mutter, Edda A.; Peterson, Bruce J.; Peucker-Ehrenbrink, Bernhard; Raymond, Peter A.; Schuster, Paul F.; Scott, Lindsay; Staples, Robin; Striegl, Robert G.; Tretiakov, Mikhail; Zhulidov, Alexander V.; Zimov, Nikita; Zimov, Sergey; Holmes, Robert M.</b> (2023). Recent trends in the chemistry of major northern rivers signal widespread Arctic change. <i>Nature Geoscience 16(9)</i>: 789-796. <a href=\"https://dx.doi.org/10.1038/s41561-023-01247-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01247-7</a>","StandardTitle":"Recent trends in the chemistry of major northern rivers signal widespread Arctic change","AuthorsString":"Tank, Suzanne E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":319476,"RR":"<b>Tokarska, K.B.; Schleussner, C.-F.; Rogelj, J.; Stolpe, M.B.; Matthews, H.D.; Pfleiderer, P.; Gillett, N.P.</b> (2019). Recommended temperature metrics for carbon budget estimates, model evaluation and climate policy. <i>Nature Geoscience 12(12)</i>: 964-971. <a href=\"https://dx.doi.org/10.1038/s41561-019-0493-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0493-5</a>","StandardTitle":"Recommended temperature metrics for carbon budget estimates, model evaluation and climate policy","AuthorsString":"Tokarska, K.B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392276,"RR":"(2024). Reconstruction of Patagonia’s glacial history informs key global climate drivers. <i>Nature Geoscience 17(5)</i>: 381-382. <a href=\"https://dx.doi.org/10.1038/s41561-024-01437-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01437-x</a>","StandardTitle":"Reconstruction of Patagonia’s glacial history informs key global climate drivers","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":435869,"RR":"<b>Ochwat, N.; Scambos, T.; Anderson, R.S.; Winberry, J.P.; Luckman, A.; Berthier, E.; Bernat, M.; Antropova, Y.K.</b> (2025). Record grounded glacier retreat caused by an ice plain calving process. <i>Nature Geoscience 18(11)</i>: 1117-1124. <a href=\"https://dx.doi.org/10.1038/s41561-025-01802-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01802-4</a>","StandardTitle":"Record grounded glacier retreat caused by an ice plain calving process","AuthorsString":"Ochwat, N. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":365658,"RR":"<b>Peng, Y.; Hattori, S.; Zuo, P.; Ma, H.; Bao, H.</b> (2023). Record of pre-industrial atmospheric sulfate in continental interiors. <i>Nature Geoscience 16(7)</i>: 619-624. <a href=\"https://dx.doi.org/10.1038/s41561-023-01211-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01211-5</a>","StandardTitle":"Record of pre-industrial atmospheric sulfate in continental interiors","AuthorsString":"Peng, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":360452,"RR":"<b>Kvale, K.; Oschlies, A.</b> (2023). Recovery from microplastic-induced marine deoxygenation may take centuries. <i>Nature Geoscience 16(1)</i>: 10-12. <a href=\"https://dx.doi.org/10.1038/s41561-022-01096-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01096-w</a>","StandardTitle":"Recovery from microplastic-induced marine deoxygenation may take centuries","AuthorsString":"Kvale, K.; Oschlies, A.","BibLvlCode":"AS"},{"BRefID":291294,"RR":"<b>Klocke, D.; Brueck, M.; Hohenegger, C.; Stevens, B.</b> (2017). Rediscovery of the doldrums in storm-resolving simulations over the tropical Atlantic. <i>Nature Geoscience 10(12)</i>: 891-896. <a href=\"https://dx.doi.org/10.1038/s41561-017-0005-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0005-4</a>","StandardTitle":"Rediscovery of the doldrums in storm-resolving simulations over the tropical Atlantic","AuthorsString":"Klocke, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":327889,"RR":"<b>Roerdink, D.</b> (2020). Redrawing the early sulfur cycle. <i>Nature Geoscience 13(8)</i>: 526-527. <a href=\"https://dx.doi.org/10.1038/s41561-020-0608-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0608-z</a>","StandardTitle":"Redrawing the early sulfur cycle","AuthorsString":"Roerdink, D.","BibLvlCode":"AS"},{"BRefID":298382,"RR":"<b>Pereira, R.; Ashton, I.; Sabbaghzadeh, B.; Shutler, J.D.; Upstill-Goddard, R.C.</b> (2018). Reduced air–sea CO<sub>2</sub> exchange in the Atlantic Ocean due to biological surfactants. <i>Nature Geoscience 11(7)</i>: 492-496. <a href=\"https://dx.doi.org/10.1038/s41561-018-0136-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0136-2</a>","StandardTitle":"Reduced air–sea CO<sub>2</sub> exchange in the Atlantic Ocean due to biological surfactants","AuthorsString":"Pereira, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":320981,"RR":"<b>Ferré, B.; Jansson, P.G.; Moser, M.; Serov, P.; Portnov, A.; Graves, C.A.; Panieri, G.; Gründger, F.; Berndt, C.; Lehmann, M.F.; Niemann, H.</b> (2020). Reduced methane seepage from Arctic sediments during cold bottom-water conditions. <i>Nature Geoscience 13(2)</i>: 144-148. <a href=\"https://dx.doi.org/10.1038/s41561-019-0515-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0515-3</a>","StandardTitle":"Reduced methane seepage from Arctic sediments during cold bottom-water conditions","AuthorsString":"Ferré, B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":287576,"RR":"<b>Kim, J.-S.; Kug, J.-S.; Jeong, S.-J.; Huntzinger, D.N.; Michalak, A.M.; Schwalm, C.R.; Wei, Y.; Schaefer, K.</b> (2017). Reduced North American terrestrial primary productivity linked to anomalous Arctic warming. <i>Nature Geoscience 10(8)</i>: 572-576. <a href=\"https://dx.doi.org/10.1038/ngeo2986\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2986</a>","StandardTitle":"Reduced North American terrestrial primary productivity linked to anomalous Arctic warming","AuthorsString":"Kim, J.-S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":414045,"RR":"<b>Chang, I.; Gao, L.; Adebiyi, A.; Doherty, S.J.; Painemal, D.; Smith, W.L.; Lenhardt, E.D.; Fakoya, A.A.; Flynn, C.J.; Zheng, J.; Yang, Z.; Castellanos, P.; da Silva, A.M.; Zhang, Z.; Wood, R.; Zuidema, P.; Christopher, S.A.; Redemann, J.</b> (2025). Regional aerosol warming enhanced by the diurnal cycle of low cloud. <i>Nature Geoscience 18(8)</i>: 702-708. <a href=\"https://dx.doi.org/10.1038/s41561-025-01740-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01740-1</a>","StandardTitle":"Regional aerosol warming enhanced by the diurnal cycle of low cloud","AuthorsString":"Chang, I. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291791,"RR":"<b>McGregor, H.V.</b> (2018). Regional climate goes global. <i>Nature Geoscience 11(1)</i>: 18-19. <a href=\"https://dx.doi.org/10.1038/s41561-017-0046-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0046-8</a>","StandardTitle":"Regional climate goes global","AuthorsString":"McGregor, H.V.","BibLvlCode":"AS"},{"BRefID":383525,"RR":"<b>Oelsmann, J.; Marcos, M.; Passaro, M.; Sanchez, L.; Dettmering, D.; Dangendorf, S.; Seitz, F.</b> (2024). Regional variations in relative sea-level changes influenced by nonlinear vertical land motion. <i>Nature Geoscience 17(2)</i>: 137-144. <a href=\"https://dx.doi.org/10.1038/s41561-023-01357-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01357-2</a>","StandardTitle":"Regional variations in relative sea-level changes influenced by nonlinear vertical land motion","AuthorsString":"Oelsmann, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":353956,"RR":"<b>Braddock, S.; Hall, B.L.; Johnson, J.S.; Balco, G.; Spoth, M.; Whitehouse, P.L.; Campbell, S.; Goehring, B.M.; Rood, D.H.; Woodward, J.</b> (2022). Relative sea-level data preclude major late Holocene ice-mass change in Pine Island Bay. <i>Nature Geoscience 15(7)</i>: 568-572. <a href=\"https://dx.doi.org/10.1038/s41561-022-00961-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00961-y</a>","StandardTitle":"Relative sea-level data preclude major late Holocene ice-mass change in Pine Island Bay","AuthorsString":"Braddock, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":230835,"RR":"<b>Stocchi, P.; Escutia, C.; Houben, A.J.P.; Vermeersen, B.L.A.; Bijl, P.K.; Brinkhuis, H.; DeConto , R.M.; Galeotti, S.;  Passchier, S.; Pollard, D.; IODP Expedition 318 Scientists; Houben, A.J.P.</b> (2013). Relative sea-level rise around East Antarctica during Oligocene glaciation. <i>Nature Geoscience 6(5)</i>: 380-384. <a href=\"http://dx.doi.org/10.1038/NGEO1783\" target=\"_blank\">dx.doi.org/10.1038/NGEO1783</a>","StandardTitle":"Relative sea-level rise around East Antarctica during Oligocene glaciation","AuthorsString":"Stocchi, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":319474,"RR":"<b>Gerrits, A.R.; Inglis, E.C.; Dragovic, B.; Starr, P.G.; Baxter, E.F.; Burton, K.W.</b> (2019). Release of oxidizing fluids in subduction zones recorded by iron isotope zonation in garnet. <i>Nature Geoscience 12(12)</i>: 1029-1033. <a href=\"https://dx.doi.org/10.1038/s41561-019-0471-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0471-y</a>","StandardTitle":"Release of oxidizing fluids in subduction zones recorded by iron isotope zonation in garnet","AuthorsString":"Gerrits, A.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":391805,"RR":"<b>Fan, J.; Zhao, D.; Li, C.; Liu, L.; Dong, D.</b> (2024). Remnants of shifting early Cenozoic Pacific lower mantle flow imaged beneath the Philippine Sea Plate. <i>Nature Geoscience 17(4)</i>: 347-352. <a href=\"https://dx.doi.org/10.1038/s41561-024-01404-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01404-6</a>","StandardTitle":"Remnants of shifting early Cenozoic Pacific lower mantle flow imaged beneath the Philippine Sea Plate","AuthorsString":"Fan, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":216507,"RR":"<b>Caress, D.W.; Clague, D.A.; Paduan, J.B.; Martin, J.F.; Dreyer, B.M.; Chadwick Jr., W.W.; Denny, A.; Kelley, D.S.</b> (2012). Repeat bathymetric surveys at 1-metre resolution of lava flows erupted at Axial Seamount in April 2011. <i>Nature Geoscience 5(7)</i>: 483-488. <a href=\"http://dx.doi.org/10.1038/ngeo1496\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1496</a>","StandardTitle":"Repeat bathymetric surveys at 1-metre resolution of lava flows erupted at Axial Seamount in April 2011","AuthorsString":"Caress, D.W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":287573,"RR":"<b>Ho, S.L.; Laepple, T.</b> (2017). Reply to 'Eocene temperature gradients'. <i>Nature Geoscience 10(8)</i>: 539-540. <a href=\"https://dx.doi.org/10.1038/ngeo2998\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2998</a>","StandardTitle":"Reply to 'Eocene temperature gradients'","AuthorsString":"Ho, S.L.; Laepple, T.","BibLvlCode":"AS"},{"BRefID":350634,"RR":"<b>Caesar, L.; McCarthy, G.D.; Thornalley, D.J.R.; Cahill, N.; Rahmstorf, S.</b> (2022). Reply to: Atlantic circulation change still uncertain. <i>Nature Geoscience 15</i>: 168-170. <a href=\"https://dx.doi.org/10.1038/s41561-022-00897-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00897-3</a>","StandardTitle":"Reply to: Atlantic circulation change still uncertain","AuthorsString":"Caesar, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":337164,"RR":"<b>Kench, P.S.; McLean, R.F.; Wang, X.; Owen, S.D.; Ryan, E.; Morgan, K.M.; Lin, K.; Roy, K.</b> (2021). Reply to: Climate did not drive Common Era Maldivian sea-level lowstands. <i>Nature Geoscience 14(5)</i>: 276-277. <a href=\"https://hdl.handle.net/10.1038/s41561-021-00732-1\" target=\"_blank\">https://hdl.handle.net/10.1038/s41561-021-00732-1</a>","StandardTitle":"Reply to: Climate did not drive Common Era Maldivian sea-level lowstands","AuthorsString":"Kench, P.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":325384,"RR":"<b>Polissar, P.J.; Rose, C.; Uno, K.T.; Phelps, S.R.; deMenocal, P.</b> (2020). Reply to: Multiple drivers of Miocene C<sub>4</sub> ecosystem expansions. <i>Nature Geoscience 13(7)</i>: 465-467. <a href=\"https://dx.doi.org/10.1038/s41561-020-0591-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0591-4</a>","StandardTitle":"Reply to: Multiple drivers of Miocene C<sub>4</sub> ecosystem expansions","AuthorsString":"Polissar, P.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":308736,"RR":"<b>Marcantonio, F.; Loveley, M.R.; Schmidt, M.W.; Hertzberg, J.E.</b> (2019). Reply to: No evidence for equatorial Pacific dust fertilization. <i>Nature Geoscience 12(3)</i>: 156-156. <a href=\"https://dx.doi.org/10.1038/s41561-019-0305-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0305-y</a>","StandardTitle":"Reply to: No evidence for equatorial Pacific dust fertilization","AuthorsString":"Marcantonio, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":349086,"RR":"<b>Shiozaki, T.; Inomura, K.; Fujiwara, A.; Hirose, Y.; Hashihama, F.; Harada, N.</b> (2022). Reply to: Questioning high nitrogen fixation rate measurements in the Southern Ocean. <i>Nature Geoscience 15(1)</i>: 31-32. <a href=\"https://dx.doi.org/10.1038/s41561-021-00874-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00874-2</a>","StandardTitle":"Reply to: Questioning high nitrogen fixation rate measurements in the Southern Ocean","AuthorsString":"Shiozaki, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":240976,"RR":"<b>Sibert, E.C.; Hull, P.M.; Norris, R.D.</b> (2014). Resilience of Pacific pelagic fish across the Cretaceous/Palaeogene mass extinction. <i>Nature Geoscience 7(9)</i>: 667–670. <a href=\"http://dx.doi.org/10.1038/ngeo2227\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2227</a>","StandardTitle":"Resilience of Pacific pelagic fish across the Cretaceous/Palaeogene mass extinction","AuthorsString":"Sibert, E.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":294040,"RR":"<b>Paolo, F.S.; Padman, L.; Fricker, H.A.; Adusumilli, S.; Howard, S.; Siegfried, M.R.</b> (2018). Response of Pacific-sector Antarctic ice shelves to the El Niño/Southern Oscillation. <i>Nature Geoscience 11(2)</i>: 121-126. <a href=\"https://dx.doi.org/10.1038/s41561-017-0033-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0033-0</a>","StandardTitle":"Response of Pacific-sector Antarctic ice shelves to the El Niño/Southern Oscillation","AuthorsString":"Paolo, F.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296641,"RR":"<b>Webster, J.M.; Braga, J.C.; Humblet, M.; Potts, D.C.; Iryu, Y.; Yokoyama, Y.; Fujita, K.; Bourillot, R.; Esat, T.M.; Fallon, S.; Thompson, W.G.; Thomas, A.L.; Kan, H.; McGregor, H.V.; Hinestrosa, G.; Obrochta, S.P.; Lougheed, B.C.</b> (2018). Response of the Great Barrier Reef to sea-level and environmental changes over the past 30,000 years. <i>Nature Geoscience 11(6)</i>: 426-432. <a href=\"https://dx.doi.org/10.1038/s41561-018-0127-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0127-3</a>","StandardTitle":"Response of the Great Barrier Reef to sea-level and environmental changes over the past 30,000 years","AuthorsString":"Webster, J.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":319470,"RR":"<b>Bressac, M.; Guieu, C.; Ellwood, M.J.; Tagliabue, A.; Wagener, T.; Laurenceau-Cornec, E.C.; Whitby, H.; Sarthou, G.; Boyd, P.W.</b> (2019). Resupply of mesopelagic dissolved iron controlled by particulate iron composition. <i>Nature Geoscience 12(12)</i>: 995-1000. <a href=\"https://dx.doi.org/10.1038/s41561-019-0476-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0476-6</a>","StandardTitle":"Resupply of mesopelagic dissolved iron controlled by particulate iron composition","AuthorsString":"Bressac, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":393300,"RR":"<b>Tsutsumi, Y.; Sakamoto, N.; Hirose, K.; Tagawa, S.; Umemoto, K.; Ohishi, Y.; Yurimoto, H.</b> (2024). Retention of water in subducted slabs under core–mantle boundary conditions. <i>Nature Geoscience 17(7)</i>: 697-704. <a href=\"https://dx.doi.org/10.1038/s41561-024-01464-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01464-8</a>","StandardTitle":"Retention of water in subducted slabs under core–mantle boundary conditions","AuthorsString":"Tsutsumi, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":405433,"RR":"<b>Pfleiderer, P.; Frölicher, T.L.; Kropf, C.M.; Lamboll, R.D.; Lejeune, Q.; Capela Lourenço, T.; Maussion, F.; McCaughey, J.W.; Quilcaille, Y.; Rogelj, J.; Sanderson, B.; Schuster, L.; Sillmann, J.; Smith, C.; Theokritoff, E.; Schleussner, C.-F.</b> (2025). Reversal of the impact chain for actionable climate information. <i>Nature Geoscience 18(1)</i>: 10-19. <a href=\"https://dx.doi.org/10.1038/s41561-024-01597-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01597-w</a>","StandardTitle":"Reversal of the impact chain for actionable climate information","AuthorsString":"Pfleiderer, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":365451,"RR":"(2023). Reversing climate overshoot. <i>Nature Geoscience 16(6)</i>: 467. <a href=\"https://dx.doi.org/10.1038/s41561-023-01213-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01213-3</a>","StandardTitle":"Reversing climate overshoot","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":356589,"RR":"<b>Jurikova, H.</b> (2022). Reversing Earth’s carbon engine. <i>Nature Geoscience 15(10)</i>: 756-757. <a href=\"https://dx.doi.org/10.1038/s41561-022-01031-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01031-z</a>","StandardTitle":"Reversing Earth’s carbon engine","AuthorsString":"Jurikova, H.","BibLvlCode":"AS"},{"BRefID":298393,"RR":"<b>Resplandy, L.; Keeling, R.F.; Rodenbeck, C.; Stephens, B.B.; Khatiwala, S.; Rodgers, K.B.; Long, M.C.; Bopp, L.; Tans, P.P.</b> (2018). Revision of global carbon fluxes based on a reassessment of oceanic and riverine carbon transport. <i>Nature Geoscience 11(7)</i>: 504-509. <a href=\"https://dx.doi.org/10.1038/s41561-018-0151-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0151-3</a>","StandardTitle":"Revision of global carbon fluxes based on a reassessment of oceanic and riverine carbon transport","AuthorsString":"Resplandy, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":344776,"RR":"<b>Liu, M.; Zhang, Q.; Maavara, T.; Liu, S.; Wang, X.; Raymond, P.A.</b> (2021). Rivers as the largest source of mercury to coastal oceans worldwide. <i>Nature Geoscience 14(9)</i>: 672-677. <a href=\"https://dx.doi.org/10.1038/s41561-021-00793-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00793-2</a>","StandardTitle":"Rivers as the largest source of mercury to coastal oceans worldwide","AuthorsString":"Liu, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":363311,"RR":"(2023). Robotic exploration of sub-ice shelf melting and freezing processes. <i>Nature Geoscience 16(3)</i>: 198-199. <a href=\"https://dx.doi.org/10.1038/s41561-023-01130-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01130-5</a>","StandardTitle":"Robotic exploration of sub-ice shelf melting and freezing processes","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":243200,"RR":"<b>Mori, M.; Watanabe, M.; Shiogama, H.; Inoue, J.; Kimoto, M.</b> (2014). Robust Arctic sea-ice influence on the frequent Eurasian cold winters in past decades. <i>Nature Geoscience 7(12)</i>: 869–873. <a href=\"http://dx.doi.org/10.1038/ngeo2277\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2277</a>","StandardTitle":"Robust Arctic sea-ice influence on the frequent Eurasian cold winters in past decades","AuthorsString":"Mori, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":249480,"RR":"<b>McGregor, H.V.; Evans, M.N.; Goosse, H.; Leduc, G.; Martrat, B.; Addison, J.A.; Mortyn, P. Graham; Oppo, D.W.; Seidenkrantz, M.-S.; Sicre, M.-A.; Phipps, S.J.; Selvaraj, K.; Thirumalai, K.; Filipsson, H.L.; Ersek, V.</b> (2015). Robust global ocean cooling trend for the pre-industrial Common Era. <i>Nature Geoscience 8(9)</i>: 671-677. <a href=\"http://dx.doi.org/10.1038/ngeo2510\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2510</a>","StandardTitle":"Robust global ocean cooling trend for the pre-industrial Common Era","AuthorsString":"McGregor, H.V. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":302785,"RR":"<b>Pithan, F.; Svensson, G.; Caballero, R.; Chechin, D.; Cronin, T.W.; Ekman, A.M.L.; Neggers, R.; Shupe, M.D.; Solomon, A.; Tjernström, M.; Wendisch, M.</b> (2018). Role of air-mass transformations in exchange between the Arctic and mid-latitudes. <i>Nature Geoscience 11(11)</i>: 805-812. <a href=\"https://dx.doi.org/10.1038/s41561-018-0234-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0234-1</a>","StandardTitle":"Role of air-mass transformations in exchange between the Arctic and mid-latitudes","AuthorsString":"Pithan, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":309973,"RR":"<b>Nilsson-Kerr, K.; Anand, P.; Sexton, P.F.; Leng, M.J.; Misra, S.; Clemens, S.C.; Hammond, S.J.</b> (2019). Role of Asian summer monsoon subsystems in the inter-hemispheric progression of deglaciation. <i>Nature Geoscience 12(4)</i>: 290-295. <a href=\"https://dx.doi.org/10.1038/s41561-019-0319-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0319-5</a>","StandardTitle":"Role of Asian summer monsoon subsystems in the inter-hemispheric progression of deglaciation","AuthorsString":"Nilsson-Kerr, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":319473,"RR":"<b>Faccenna, C.; Glišovic, P.; Forte, A.; Becker, T.W.; Garzanti, E.; Sembroni, A.; Gvirtzman, Z.</b> (2019). Role of dynamic topography in sustaining the Nile River over 30 million years. <i>Nature Geoscience 12(12)</i>: 1012-1017. <a href=\"https://dx.doi.org/10.1038/s41561-019-0472-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0472-x</a>","StandardTitle":"Role of dynamic topography in sustaining the Nile River over 30 million years","AuthorsString":"Faccenna, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":294039,"RR":"<b>Wernli, H.; Papritz, L.</b> (2018). Role of polar anticyclones and mid-latitude cyclones for Arctic summertime sea-ice melting. <i>Nature Geoscience 11(2)</i>: 108-113. <a href=\"https://dx.doi.org/10.1038/s41561-017-0041-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0041-0</a>","StandardTitle":"Role of polar anticyclones and mid-latitude cyclones for Arctic summertime sea-ice melting","AuthorsString":"Wernli, H.; Papritz, L.","BibLvlCode":"AS"},{"BRefID":211507,"RR":"<b>Chauvel, C.; Lewin, E.; Carpentier, M.; Arndt, N.T.; Marini, J.-C.</b> (2007). Role of recycled oceanic basalt and sediment in generating the Hf–Nd mantle array. <i>Nature Geoscience 1(1)</i>: 64-67. <a href=\"http://dx.doi.org/10.1038/ngeo.2007.51\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo.2007.51</a>","StandardTitle":"Role of recycled oceanic basalt and sediment in generating the Hf–Nd mantle array","AuthorsString":"Chauvel, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":211511,"RR":"<b>Weis, D.; Garcia, M.O.; Rhodes, J. M.; Jellinek, M.; Scoates, J.S.</b> (2011). Role of the deep mantle in generating the compositional asymmetry of the Hawaiian mantle plume. <i>Nature Geoscience 4(12)</i>: 831-838. <a href=\"http://dx.doi.org/10.1038/ngeo1328\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1328</a>","StandardTitle":"Role of the deep mantle in generating the compositional asymmetry of the Hawaiian mantle plume","AuthorsString":"Weis, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":311933,"RR":"<b>Tinto, K.J.; Padman, L.; Siddoway, C.S.; Springer, S.R.; Fricker, H.A.; Das, I.; Caratori-Tontini, F.; Porter, D.F.; Frearson, N.P.; Howard, S.L.; Siegfried, M.R.; Mosbeux, C.; Becker, M.K.; Bertinato, C.; Boghosian, A.; Brady, N.; Burton, B.L.; Chu, W.; Cordero, S.I.; Dhakal, T.; Dong, L.; Gustafson, C.D.; Keeshin, S.; Locke, C.; Lockett, A.; O’Brien, G.; Spergel, J.J.; Starke, S.E.; Tankersley, M.; Wearing, M.G.; Bell, R.E.</b> (2019). Ross Ice Shelf response to climate driven by the tectonic imprint on seafloor bathymetry. <i>Nature Geoscience 12(6)</i>: 441-449. <a href=\"https://dx.doi.org/10.1038/s41561-019-0370-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0370-2</a>","StandardTitle":"Ross Ice Shelf response to climate driven by the tectonic imprint on seafloor bathymetry","AuthorsString":"Tinto, K.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":363310,"RR":"(2023). Satellite data shows Antarctic Peninsula glaciers flow faster in summer. <i>Nature Geoscience 16(3)</i>: 196-197. <a href=\"https://dx.doi.org/10.1038/s41561-023-01135-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01135-0</a>","StandardTitle":"Satellite data shows Antarctic Peninsula glaciers flow faster in summer","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":240975,"RR":"<b>Chen, Y.-C.; Christensen, M.W.; Stephens, G.L.; Seinfeld, J.H.</b> (2014). Satellite-based estimate of global aerosol–cloud radiative forcing by marine warm clouds. <i>Nature Geoscience 7(9)</i>: 643–646. <a href=\"http://dx.doi.org/10.1038/ngeo2214\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2214</a>","StandardTitle":"Satellite-based estimate of global aerosol–cloud radiative forcing by marine warm clouds","AuthorsString":"Chen, Y.-C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":345723,"RR":"(2021). Scaling through ocean carbon. <i>Nature Geoscience 14(10)</i>: 705-705. <a href=\"https://dx.doi.org/10.1038/s41561-021-00840-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00840-y</a>","StandardTitle":"Scaling through ocean carbon","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":368753,"RR":"<b>Hoffman, A.O.; Holschuh, N.; Mueller, M.; Paden, J.; Muto, A.; Ariho, G.; Brigham, C.; Christian, J.E.; Davidge, L.; Heitmann, E.; Hills, B.; Horlings, A.; Morey, S.; O’Connor, G.; Fudge, T.J.; Steig, E.J.; Christianson, K.</b> (2023). Scars of tectonism promote ice-sheet nucleation from Hercules Dome into West Antarctica. <i>Nature Geoscience 16(11)</i>: 1005-1013. <a href=\"https://dx.doi.org/10.1038/s41561-023-01265-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01265-5</a>","StandardTitle":"Scars of tectonism promote ice-sheet nucleation from Hercules Dome into West Antarctica","AuthorsString":"Hoffman, A.O. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":290671,"RR":"<b>Ryan, M.A.</b> (2017). Science versus political realities. <i>Nature Geoscience 10(11)</i>: 806-808. <a href=\"https://dx.doi.org/10.1038/ngeo3049\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3049</a>","StandardTitle":"Science versus political realities","AuthorsString":"Ryan, M.A.","BibLvlCode":"AS"},{"BRefID":303661,"RR":"<b>Gutscher, M.-A.</b> (2018). Scraped by flat-slab subduction. <i>Nature Geoscience 11(12)</i>: 890-891. <a href=\"https://dx.doi.org/10.1038/s41561-018-0270-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0270-x</a>","StandardTitle":"Scraped by flat-slab subduction","AuthorsString":"Gutscher, M.-A.","BibLvlCode":"AS"},{"BRefID":351416,"RR":"<b>Xu, W.; Ovadnevaite, J.; Fossum, K.N.; Lin, C.; Huang, R.-J.; Ceburnis, D.; O'Dowd, C.</b> (2022). Sea spray as an obscured source for marine cloud nuclei. <i>Nature Geoscience 15(4)</i>: 282-286. <a href=\"https://dx.doi.org/10.1038/s41561-022-00917-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00917-2</a>","StandardTitle":"Sea spray as an obscured source for marine cloud nuclei","AuthorsString":"Xu, W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":260846,"RR":"<b>Bindoff, N.L.; Hobbs, W.R.</b> (2016). Sea-ice-driven shallow overturning. <i>Nature Geoscience 9(8)</i>: 569-570. <a href=\"http://dx.doi.org/10.1038/ngeo2766\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2766</a>","StandardTitle":"Sea-ice-driven shallow overturning","AuthorsString":"Bindoff, N.L.; Hobbs, W.R.","BibLvlCode":"AS"},{"BRefID":252691,"RR":"<b>Liu, J.; Milne, G.A.; Kopp, R.E.; Clark, P.U.; Shennan, I.</b> (2015). Sea-level constraints on the amplitude and source distribution of Meltwater Pulse 1A. <i>Nature Geoscience 9(2)</i>: 130-134. <a href=\"http://dx.doi.org/10.1038/ngeo2616\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2616</a>","StandardTitle":"Sea-level constraints on the amplitude and source distribution of Meltwater Pulse 1A","AuthorsString":"Liu, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":435873,"RR":"<b>Mukherjee, U.; De Vetter, L.; Milne, G.A.; Tarasov, L.; Steponaitis, E.; Cahill, N.; Lecavalier, B.S.; Rosenheim, B.E.; Törnqvist, T.E.</b> (2025). Sea-level rise at the end of the last deglaciation dominated by North American ice sheets. <i>Nature Geoscience 18(11)</i>: 1167-1173. <a href=\"https://dx.doi.org/10.1038/s41561-025-01806-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01806-0</a>","StandardTitle":"Sea-level rise at the end of the last deglaciation dominated by North American ice sheets","AuthorsString":"Mukherjee, U. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":351961,"RR":"<b>Cerpa, N.G.; Arcay, D.; Padrón-Navarta, J.A.</b> (2022). Sea-level stability over geological time owing to limited deep subduction of hydrated mantle. <i>Nature Geoscience 15(5)</i>: 423-428. <a href=\"https://dx.doi.org/10.1038/s41561-022-00924-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00924-3</a>","StandardTitle":"Sea-level stability over geological time owing to limited deep subduction of hydrated mantle","AuthorsString":"Cerpa, N.G.; Arcay, D.; Padrón-Navarta, J.A.","BibLvlCode":"AS"},{"BRefID":216510,"RR":"<b>Chadwick Jr., W.W.; Nooner, S.L.; Butterfield, D.A.; Lilley, M.D.</b> (2012). Seafloor deformation and forecasts of the April 2011 eruption at Axial Seamount. <i>Nature Geoscience 5(7)</i>: 474-477. <a href=\"http://dx.doi.org/10.1038/ngeo1464\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1464</a>","StandardTitle":"Seafloor deformation and forecasts of the April 2011 eruption at Axial Seamount","AuthorsString":"Chadwick Jr., W.W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":240978,"RR":"<b>Kessler, J.</b> (2014). Seafloor methane: Atlantic bubble bath. <i>Nature Geoscience 7(9)</i>: 625–626. <a href=\"http://dx.doi.org/10.1038/ngeo2238\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2238</a>","StandardTitle":"Seafloor methane: Atlantic bubble bath","AuthorsString":"Kessler, J.","BibLvlCode":"AS"},{"BRefID":296435,"RR":"<b>Fourqurean, J.W.; Duarte, C.M.; Kennedy, H.; Marba, N.; Holmer, M.; Mateo, M.A.; Apostolaki, E.T.; Kendrick, G.A.; Krause-Jensen, D.; McGlathery, K.J.; Serrano, O.</b> (2012). Seagrass ecosystems as a globally significant carbon stock. <i>Nature Geoscience 5(7)</i>: 505-509. <a href=\"https://dx.doi.org/10.1038/ngeo1477\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo1477</a>","StandardTitle":"Seagrass ecosystems as a globally significant carbon stock","AuthorsString":"Fourqurean, J.W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":405431,"RR":"<b>Brandt, P.; Körner, M.; Moum, J.N.; Roch, M.; Subramaniam, A.; Czeschel, R.; Krahmann, G.; Dengler, M.; Kiko, R.</b> (2025). Seasonal productivity of the equatorial Atlantic shaped by distinct wind-driven processes. <i>Nature Geoscience 18(1)</i>: 84-90. <a href=\"https://dx.doi.org/10.1038/s41561-024-01609-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01609-9</a>","StandardTitle":"Seasonal productivity of the equatorial Atlantic shaped by distinct wind-driven processes","AuthorsString":"Brandt, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":283785,"RR":"<b>Kendrick, M.A.; Hémond, C.; Kamenetsky, V.S.; Danyushevsky, L.; Devey, C.W.; Rodemann, T.; Jackson, M.G.; Perfit, M.R.</b> (2017). Seawater cycled throughout Earth’s mantle in partially serpentinized lithosphere. <i>Nature Geoscience 10(3)</i>: 222-228. <a href=\"http://dx.doi.org/10.1038/ngeo2902\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2902</a>","StandardTitle":"Seawater cycled throughout Earth’s mantle in partially serpentinized lithosphere","AuthorsString":"Kendrick, M.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":365662,"RR":"<b>Wang, Y.; Cao, Z.; Peng, L.; Liu, L.; Chen, L.; Lundstrom, C.; Peng, D.; Yang, X.</b> (2023). Secular craton evolution due to cyclic deformation of underlying dense mantle lithosphere. <i>Nature Geoscience 16(7)</i>: 637-645. <a href=\"https://dx.doi.org/10.1038/s41561-023-01203-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01203-5</a>","StandardTitle":"Secular craton evolution due to cyclic deformation of underlying dense mantle lithosphere","AuthorsString":"Wang, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":354971,"RR":"<b>Li, L.; Aitken, A.R.A.; Lindsay, M.D.; Kulessa, B.</b> (2022). Sedimentary basins reduce stability of Antarctic ice streams through groundwater feedbacks. <i>Nature Geoscience 15(8)</i>: 645-650. <a href=\"https://dx.doi.org/10.1038/s41561-022-00992-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00992-5</a>","StandardTitle":"Sedimentary basins reduce stability of Antarctic ice streams through groundwater feedbacks","AuthorsString":"Li, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":437134,"RR":"<b>Mertens, C.; Paradis, S.; Hemingway, J.D.</b> (2026). Sedimentary conditions drive modern pyrite burial flux to exceed oxidation. <i>Nature Geoscience 19(1)</i>: 99-105. <a href=\"https://dx.doi.org/10.1038/s41561-025-01855-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01855-5</a>","StandardTitle":"Sedimentary conditions drive modern pyrite burial flux to exceed oxidation","AuthorsString":"Mertens, C.; Paradis, S.; Hemingway, J.D.","BibLvlCode":"AS"},{"BRefID":260855,"RR":"<b>VanderBeek, B.P.; Toomey, D.R.; Hooft, E.E.E.; Wilcock, W.S.D.</b> (2016). Segmentation of mid-ocean ridges attributed to oblique mantle divergence. <i>Nature Geoscience 9(8)</i>: 636-642. <a href=\"http://dx.doi.org/10.1038/ngeo2745\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2745</a>","StandardTitle":"Segmentation of mid-ocean ridges attributed to oblique mantle divergence","AuthorsString":"VanderBeek, B.P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":419033,"RR":"<b>Duarte, J.C.; Riel, N.; Civiero, C.; Silva, S.; Rosas, F.M.; Schellart, W.P.; Almeida, J.; Terrinha, P.; Ribeiro, A.</b> (2025). Seismic evidence for oceanic plate delamination offshore Southwest Iberia. <i>Nature Geoscience 18(10)</i>: 1034-1040. <a href=\"https://dx.doi.org/10.1038/s41561-025-01781-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01781-6</a>","StandardTitle":"Seismic evidence for oceanic plate delamination offshore Southwest Iberia","AuthorsString":"Duarte, J.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":241875,"RR":"<b>Géli, L.; Piau, J.-M.; Dziak, R.P.; Maury, V.; Fitzenz, D.; Coutellier, Q.; Henry, P.</b> (2014). Seismic precursors linked to super-critical fluids at oceanic transform faults. <i>Nature Geoscience 7(10)</i>: 757-761. <a href=\"http://dx.doi.org/10.1038/ngeo2244\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2244</a>","StandardTitle":"Seismic precursors linked to super-critical fluids at oceanic transform faults","AuthorsString":"Géli, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":300328,"RR":"<b>Schwarz, C.; Gourgue, O.; van Belzen, J.; Zhu, Z.; Bouma, T.J.; van de Koppel, J.; Ruessink, G.; Claude, N.; Temmerman, S.</b> (2018). Self-organization of a biogeomorphic landscape controlled by plant life-history traits. <i>Nature Geoscience 11(7)</i>: 672-677. <a href=\"https://doi.org/10.1038/s41561-018-0180-y\" target=\"_blank\">https://doi.org/10.1038/s41561-018-0180-y</a>","StandardTitle":"Self-organization of a biogeomorphic landscape controlled by plant life-history traits","AuthorsString":"Schwarz, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":243945,"RR":"<b>Goodwin, P.; Williams, R.G.; Ridgwell, A.</b> (2015). Sensitivity of climate to cumulative carbon emissions due to compensation of ocean heat and carbon uptake. <i>Nature Geoscience 8(1)</i>: 29-34. <a href=\"http://dx.doi.org/10.1038/ngeo2304\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2304</a>","StandardTitle":"Sensitivity of climate to cumulative carbon emissions due to compensation of ocean heat and carbon uptake","AuthorsString":"Goodwin, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":345737,"RR":"<b>Johnson, K.M.; McKay, R.M.; Etourneau, J.; Jiménez-Espejo, F.J.; Albot, A.; Riesselman, C.R.; Bertler, N.A.N.; Horgan, H.J.; Crosta, X.; Bendle, J.; Ashley, K.E.; Yamane, M.; Yokoyama, Y.; Pekar, S.F.; Escutia, C.; Dunbar, R.B.</b> (2021). Sensitivity of Holocene East Antarctic productivity to subdecadal variability set by sea ice. <i>Nature Geoscience 14(10)</i>: 762-768. <a href=\"https://dx.doi.org/10.1038/s41561-021-00816-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00816-y</a>","StandardTitle":"Sensitivity of Holocene East Antarctic productivity to subdecadal variability set by sea ice","AuthorsString":"Johnson, K.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":254715,"RR":"<b>Yu, J.; Menviel, L.; Jin, Z.D.; Thornalley, D.J.R.; Barker, S.; Marino, G.; Rohling, E.J.; Cais, Y.; Zhang, F.; Wang, X.; Dai, Y.; Chen, P.; Broecker, W.S.</b> (2016). Sequestration of carbon in the deep Atlantic during the last glaciation. <i>Nature Geoscience 9(4)</i>: 319-324. <a href=\"http://dx.doi.org/10.1038/ngeo2657\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2657</a>","StandardTitle":"Sequestration of carbon in the deep Atlantic during the last glaciation","AuthorsString":"Yu, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366509,"RR":"<b>Berndt, Christian; Planke, Sverre; Alvarez Zarikian, Carlos A.; Frieling, Joost; Jones, Morgan T.; Millett, John M.; Brinkhuis, Henk; Bünz, Stefan; Svensen, Henrik H.; Longman, Jack; Scherer, Reed P.; Karstens, Jens; Manton, Ben; Nelissen, Mei; Reed, Brandon; Faleide, Jan Inge; Huismans, Ritske S.; Agarwal, Amar; Andrews, Graham D. M.; Betlem, Peter; Bhattacharya, Joyeeta; Chatterjee, Sayantani; Christopoulou, Marialena; Clementi, Vincent J.; Ferré, Eric C.; Filina, Irina Y.; Guo, Pengyuan; Harper, Dustin T.; Lambart, Sarah; Mohn, Geoffroy; Nakaoka, Reina; Tegner, Christian; Varela, Natalia; Wang, Mengyuan; Xu, Weimu; Yager, Stacy L.</b> (2023). Shallow-water hydrothermal venting linked to the Palaeocene–Eocene Thermal Maximum. <i>Nature Geoscience 16(9)</i>: 803-809. <a href=\"https://dx.doi.org/10.1038/s41561-023-01246-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01246-8</a>","StandardTitle":"Shallow-water hydrothermal venting linked to the Palaeocene–Eocene Thermal Maximum","AuthorsString":"Berndt, Christian <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":436565,"RR":"<b>Gaina, C.</b> (2025). Shaving continents into the oceans. <i>Nature Geoscience 18(12)</i>: 1191-1192. <a href=\"https://dx.doi.org/10.1038/s41561-025-01845-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01845-7</a>","StandardTitle":"Shaving continents into the oceans","AuthorsString":"Gaina, C.","BibLvlCode":"AS"},{"BRefID":411046,"RR":"<b>Garber, J.M.; Rioux, M.; Smye, A.J.; Cruz-Uribe, A.M.; Baker, P.L.; Vervoort, J.D.; Searle, M.P.; Feineman, M.D.</b> (2025). Shear heating during rapid subduction initiation beneath the Samail Ophiolite. <i>Nature Geoscience 18(7)</i>: 653-660. <a href=\"https://dx.doi.org/10.1038/s41561-025-01711-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01711-6</a>","StandardTitle":"Shear heating during rapid subduction initiation beneath the Samail Ophiolite","AuthorsString":"Garber, J.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":351960,"RR":"<b>Hoek van Dijke, A.J.; Herold, M.; Mallick, K.; Benedict, I.; Machwitz, M.; Schlerf, M.; Pranindita, A.; Theeuwen, J.J.E.; Bastin, J.-F.; Teuling, A.J.</b> (2022). Shifts in regional water availability due to global tree restoration. <i>Nature Geoscience 15(5)</i>: 363-368. <a href=\"https://dx.doi.org/10.1038/s41561-022-00935-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00935-0</a>","StandardTitle":"Shifts in regional water availability due to global tree restoration","AuthorsString":"Hoek van Dijke, A.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":336519,"RR":"<b>Poulton, A.J.</b> (2021). Shunt or shuttle. <i>Nature Geoscience 14(4)</i>: 181-183. <a href=\"https://dx.doi.org/10.1038/s41561-021-00718-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00718-z</a>","StandardTitle":"Shunt or shuttle","AuthorsString":"Poulton, A.J.","BibLvlCode":"AS"},{"BRefID":345729,"RR":"<b>Gjermundsen, A.; Nummelin, A.; Olivié, D.; Bentsen, M.; Seland, Ø.; Schulz, M.</b> (2021). Shutdown of Southern Ocean convection controls long-term greenhouse gas-induced warming. <i>Nature Geoscience 14(10)</i>: 724-731. <a href=\"https://dx.doi.org/10.1038/s41561-021-00825-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00825-x</a>","StandardTitle":"Shutdown of Southern Ocean convection controls long-term greenhouse gas-induced warming","AuthorsString":"Gjermundsen, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":260848,"RR":"<b>Ingalls, A.E.</b> (2016). Signal from the subsurface. <i>Nature Geoscience 9(8)</i>: 572-573. <a href=\"http://dx.doi.org/10.1038/ngeo2765\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2765</a>","StandardTitle":"Signal from the subsurface","AuthorsString":"Ingalls, A.E.","BibLvlCode":"AS"},{"BRefID":233937,"RR":"<b>Sun, X.; Turchyn, A.V.</b> (2014). Significant contribution of authigenic carbonate to marine carbon burial. <i>Nature Geoscience 7(3)</i>: 201-204. <a href=\"http://dx.doi.org/10.1038/ngeo2070\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2070</a>","StandardTitle":"Significant contribution of authigenic carbonate to marine carbon burial","AuthorsString":"Sun, X.; Turchyn, A.V.","BibLvlCode":"AS"},{"BRefID":239618,"RR":"<b>Pichevin, L.E.; Ganeshram, R.S.; Geibert, W.; Thunell, R.; Hinton, R.</b> (2014). Silica burial enhanced by iron limitation in oceanic upwelling margins. <i>Nature Geoscience 7(7)</i>: 541-546. <a href=\"http://dx.doi.org/10.1038/ngeo2181\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2181</a>","StandardTitle":"Silica burial enhanced by iron limitation in oceanic upwelling margins","AuthorsString":"Pichevin, L.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366134,"RR":"<b>Henehan, M.J.</b> (2023). Silicate weathering feedback hindered by clay formation. <i>Nature Geoscience 16(8)</i>: 663-664. <a href=\"https://dx.doi.org/10.1038/s41561-023-01242-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01242-y</a>","StandardTitle":"Silicate weathering feedback hindered by clay formation","AuthorsString":"Henehan, M.J.","BibLvlCode":"AS"},{"BRefID":283779,"RR":"<b>Vance, D.; Little, S.H.; de Souza, G.F.; Khatiwala, S.; Middag, R.</b> (2017). Silicon and zinc biogeochemical cycles coupled through the Southern Ocean. <i>Nature Geoscience 10(3)</i>: 202-206. <a href=\"https://dx.doi.org/10.1038/ngeo2890\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2890</a>","StandardTitle":"Silicon and zinc biogeochemical cycles coupled through the Southern Ocean","AuthorsString":"Vance, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":355459,"RR":"<b>Amarathunga, U.; Hogg, A.M.; Rohling, E.J.; Roberts, A.P.; Grant, K.M.; Heslop, D.; Hu, P.; Liebrand, D.; Westerhold, T.; Zhao, X.; Gilmore, S.</b> (2022). Sill-controlled salinity contrasts followed post-Messinian flooding of the Mediterranean. <i>Nature Geoscience 15(9)</i>: 720-725. <a href=\"https://dx.doi.org/10.1038/s41561-022-00998-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00998-z</a>","StandardTitle":"Sill-controlled salinity contrasts followed post-Messinian flooding of the Mediterranean","AuthorsString":"Amarathunga, U. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":363727,"RR":"<b>Capotondi, A.</b> (2023). Simplifying climate complexity. <i>Nature Geoscience 16(4)</i>: 280-281. <a href=\"https://dx.doi.org/10.1038/s41561-023-01161-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01161-y</a>","StandardTitle":"Simplifying climate complexity","AuthorsString":"Capotondi, A.","BibLvlCode":"AS"},{"BRefID":345753,"RR":"<b>Alcolombri, U.; Peaudecerf, F.J.; Fernandez, V.I.; Behrendt, L.; Lee, K.S.; Stocker, R.</b> (2021). Sinking enhances the degradation of organic particles by marine bacteria. <i>Nature Geoscience 14(10)</i>: 775-780. <a href=\"https://dx.doi.org/10.1038/s41561-021-00817-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00817-x</a>","StandardTitle":"Sinking enhances the degradation of organic particles by marine bacteria","AuthorsString":"Alcolombri, U. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":246330,"RR":"<b>Walowski, K.J.; Wallace, P.J.; Hauri, E.H.; Wada, I.; Clynne, M.A.</b> (2015). Slab melting beneath the Cascade Arc driven by dehydration of altered oceanic peridotite. <i>Nature Geoscience 8(5)</i>: 404 - 408. <a href=\"http://dx.doi.org/10.1038/ngeo2417\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2417</a>","StandardTitle":"Slab melting beneath the Cascade Arc driven by dehydration of altered oceanic peridotite","AuthorsString":"Walowski, K.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":414064,"RR":"<b>Sassard, V.; Yang, X.; Liu, L.; Elliott, J.</b> (2025). Slab tearing along a subducted oceanic plate joint beneath the Alaska Peninsula. <i>Nature Geoscience 18(8)</i>: 801-807. <a href=\"https://dx.doi.org/10.1038/s41561-025-01749-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01749-6</a>","StandardTitle":"Slab tearing along a subducted oceanic plate joint beneath the Alaska Peninsula","AuthorsString":"Sassard, V. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":337176,"RR":"<b>Lindsey, E.O.; Mallick, R.; Hubbard, J.A.; Bradley, K.E.; Almeida, R.V.; Moore, J.D.P.; Bürgmann, R.; Hill, E.M.</b> (2021). Slip rate deficit and earthquake potential on shallow megathrusts. <i>Nature Geoscience 14(5)</i>: 321-326. <a href=\"https://hdl.handle.net/10.1038/s41561-021-00736-x\" target=\"_blank\">https://hdl.handle.net/10.1038/s41561-021-00736-x</a>","StandardTitle":"Slip rate deficit and earthquake potential on shallow megathrusts","AuthorsString":"Lindsey, E.O. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":365454,"RR":"<b>Bangs, Nathan L.; Morgan, Julia K.; Bell, Rebecca E.; Han, Shuoshuo; Arai, Ryuta; Kodaira, Shuichi; Gase, Andrew C.; Wu, Xinming; Davy, Richard; Frahm, Laura; Tilley, Hannah L.; Barker, Daniel H. N.; Edwards, Joel H.; Tobin, Harold J.; Reston, Tim J.; Henrys, Stuart A.; Moore, Gregory F.; Bassett, Dan; Kellett, Richard; Stucker, Valerie; Fry, Bill</b> (2023). Slow slip along the Hikurangi margin linked to fluid-rich sediments trailing subducting seamounts. <i>Nature Geoscience 16(6)</i>: 505-512. <a href=\"https://dx.doi.org/10.1038/s41561-023-01186-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01186-3</a>","StandardTitle":"Slow slip along the Hikurangi margin linked to fluid-rich sediments trailing subducting seamounts","AuthorsString":"Bangs, Nathan L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291789,"RR":"<b>Kosaka, Y.</b> (2018). Slow warming and the ocean see-saw. <i>Nature Geoscience 11(1)</i>: 12-13. <a href=\"https://dx.doi.org/10.1038/s41561-017-0038-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0038-8</a>","StandardTitle":"Slow warming and the ocean see-saw","AuthorsString":"Kosaka, Y.","BibLvlCode":"AS"},{"BRefID":393297,"RR":"<b>Trusel, L.D.</b> (2024). Slushy surface of Antarctic ice shelves. <i>Nature Geoscience 17(7)</i>: 588-589. <a href=\"https://dx.doi.org/10.1038/s41561-024-01445-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01445-x</a>","StandardTitle":"Slushy surface of Antarctic ice shelves","AuthorsString":"Trusel, L.D.","BibLvlCode":"AS"},{"BRefID":289159,"RR":"<b>Quinn, P.K.; Coffman, D.J.; Johnson, J.E.; Upchurch, L.M.; Bates, T.S.</b> (2017). Small fraction of marine cloud condensation nuclei made up of sea spray aerosol. <i>Nature Geoscience 10(9)</i>: 674-679. <a href=\"https://dx.doi.org/10.1038/ngeo3003\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3003</a>","StandardTitle":"Small fraction of marine cloud condensation nuclei made up of sea spray aerosol","AuthorsString":"Quinn, P.K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":253978,"RR":"<b>Gernon, T.M.; Hincks, T.K.; Tyrrell, T.; Rohling, E.J.; Palmer, M.R.</b> (2016). Snowball Earth ocean chemistry driven by extensive ridge volcanism during Rodinia breakup. <i>Nature Geoscience 9(3)</i>: 242-248. <a href=\"http://dx.doi.org/10.1038/ngeo2632\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2632</a>","StandardTitle":"Snowball Earth ocean chemistry driven by extensive ridge volcanism during Rodinia breakup","AuthorsString":"Gernon, T.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":395756,"RR":"<b>Gernon, T.M.; Mills, B.J.W.; Hincks, T.K.; Merdith, A.S.; Alcott, L.J.; Rohling, E.J.; Palmer, M.R.</b> (2024). Solid Earth forcing of Mesozoic oceanic anoxic events. <i>Nature Geoscience 17(9)</i>: 926-935. <a href=\"https://dx.doi.org/10.1038/s41561-024-01496-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01496-0</a>","StandardTitle":"Solid Earth forcing of Mesozoic oceanic anoxic events","AuthorsString":"Gernon, T.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":366037,"RR":"(2023). Solutions for plastic pollution. <i>Nature Geoscience 16(8)</i>: 655. <a href=\"https://dx.doi.org/10.1038/s41561-023-01255-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01255-7</a>","StandardTitle":"Solutions for plastic pollution","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":321489,"RR":"<b>Iudicone, D.</b> (2020). Some may like it hot. <i>Nature Geoscience 13(2)</i>: 98-99. <a href=\"https://dx.doi.org/10.1038/s41561-020-0535-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0535-z</a>","StandardTitle":"Some may like it hot","AuthorsString":"Iudicone, D.","BibLvlCode":"AS"},{"BRefID":437760,"RR":"<b>Struve, T.; Lamy, F.; Gäng, F.; Klages, J.P.; Kuhn, G.; Esper, O.; Lembke-Jene, L.; Winckler, G.</b> (2026). South Pacific carbon uptake controlled by West Antarctic Ice Sheet dynamics. <i>Nature Geoscience 19(2)</i>: 173-181. <a href=\"https://dx.doi.org/10.1038/s41561-025-01911-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01911-0</a>","StandardTitle":"South Pacific carbon uptake controlled by West Antarctic Ice Sheet dynamics","AuthorsString":"Struve, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":250811,"RR":"<b>Watson, A.J.; Vallis, G.K.; Nikurashin, M.</b> (2015). Southern Ocean buoyancy forcing of ocean ventilation and glacial atmospheric CO<i>2</i>. <i>Nature Geoscience 8(11)</i>: 861–864. <a href=\"http://dx.doi.org/10.1038/ngeo2538\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2538</a>","StandardTitle":"Southern Ocean buoyancy forcing of ocean ventilation and glacial atmospheric CO<i>2</i>","AuthorsString":"Watson, A.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":325385,"RR":"<b>Fogwill, C. J.; Turney, C. S. M.; Menviel, L.; Baker, A.; Weber, M. E.; Ellis, B.; Thomas, Z. A.; Golledge, N. R.; Etheridge, D.; Rubino, M.; Thornton, D. P.; van Ommen, T. D.; Moy, A. D.; Curran, M. A. J.; Davies, S.; Bird, M. I.; Munksgaard, N. C.; Rootes, C. M.; Millman, H.; Vohra, J.; Rivera, A.; Mackintosh, A.; Pike, J.; Hall, I. R.; Bagshaw, E. A.; Rainsley, E.; Bronk-Ramsey, C.; Montenari, M.; Cage, A. G.; Harris, M. R. P.; Jones, R.; Power, A.; Love, J.; Young, J.; Weyrich, L. S.; Cooper, A.</b> (2020). Southern Ocean carbon sink enhanced by sea-ice feedbacks at the Antarctic Cold Reversal. <i>Nature Geoscience 13(7)</i>: 489-497. <a href=\"https://dx.doi.org/10.1038/s41561-020-0587-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0587-0</a>","StandardTitle":"Southern Ocean carbon sink enhanced by sea-ice feedbacks at the Antarctic Cold Reversal","AuthorsString":"Fogwill, C. J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":290670,"RR":"<b>Keane, J.T.</b> (2017). Southern Ocean mixing. <i>Nature Geoscience 10(11)</i>: 805-805. <a href=\"https://dx.doi.org/10.1038/ngeo3057\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3057</a>","StandardTitle":"Southern Ocean mixing","AuthorsString":"Keane, J.T.","BibLvlCode":"AS"},{"BRefID":437135,"RR":"<b>Schine, C.M.S.; Lund Snee, J.-E.; Lyford, A.; van Dijken, G.; Arrigo, K.R.</b> (2026). Southern Ocean net primary production influenced by seismically modulated hydrothermal iron. <i>Nature Geoscience 19(1)</i>: 106-112. <a href=\"https://dx.doi.org/10.1038/s41561-025-01862-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01862-6</a>","StandardTitle":"Southern Ocean net primary production influenced by seismically modulated hydrothermal iron","AuthorsString":"Schine, C.M.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":437131,"RR":"<b>du Plessis, M.D.; Nicholson, S.-A.; Giddy, I.; Monteiro, P.M.S.; Prend, C.J.; Swart, S.</b> (2026). Southern Ocean summer warming is regulated by storm-driven mixing. <i>Nature Geoscience 19(1)</i>: 75-83. <a href=\"https://dx.doi.org/10.1038/s41561-025-01857-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01857-3</a>","StandardTitle":"Southern Ocean summer warming is regulated by storm-driven mixing","AuthorsString":"du Plessis, M.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":259369,"RR":"<b>Armour, K.C.; Marshall, J.; Scott, J.R.; Donohoe, A.; Newsom, E.R.</b> (2016). Southern Ocean warming delayed by circumpolar upwelling and equatorward transport. <i>Nature Geoscience 9(7)</i>: 549-554. <a href=\"http://dx.doi.org/10.1038/ngeo2731\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2731</a>","StandardTitle":"Southern Ocean warming delayed by circumpolar upwelling and equatorward transport","AuthorsString":"Armour, K.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291794,"RR":"<b>Karnauskas, K.B.; Lundquist, J.K.; Zhang, L.</b> (2018). Southward shift of the global wind energy resource under high carbon dioxide emissions. <i>Nature Geoscience 11(1)</i>: 38-43. <a href=\"https://dx.doi.org/10.1038/s41561-017-0029-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0029-9</a>","StandardTitle":"Southward shift of the global wind energy resource under high carbon dioxide emissions","AuthorsString":"Karnauskas, K.B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":368756,"RR":"<b>Wang, X.; Algeo, T.J.; Li, C.; Zhu, M.</b> (2023). Spatial pattern of marine oxygenation set by tectonic and ecological drivers over the Phanerozoic. <i>Nature Geoscience 16(11)</i>: 1020-1026. <a href=\"https://dx.doi.org/10.1038/s41561-023-01296-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01296-y</a>","StandardTitle":"Spatial pattern of marine oxygenation set by tectonic and ecological drivers over the Phanerozoic","AuthorsString":"Wang, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":330724,"RR":"<b>van Dijk, J.; Fernandez, A.; Bernasconi, S.M.; Caves Rugenstein, J.K.; Passey, S.R.; White, T.</b> (2020). Spatial pattern of super-greenhouse warmth controlled by elevated specific humidity. <i>Nature Geoscience 13(11)</i>: 739-744. <a href=\"https://dx.doi.org/10.1038/s41561-020-00648-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00648-2</a>","StandardTitle":"Spatial pattern of super-greenhouse warmth controlled by elevated specific humidity","AuthorsString":"van Dijk, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":437761,"RR":"<b>Patterson, Molly O.; Rosenberg, Christiana; Seki, Osamu; Yamamoto, Masanobu; Romero, Oscar E.; Nelissen, Mei; Sangiorgi, Francesca; Golledge, Nicholas R.; Grant, Georgia; Arnuk, William D.; Keisling, Benjamin; Naish, Timothy; Levy, Richard; Meyers, Stephen; Sullivan, Nicholas; Ash, Jeanine; Kulhanek, Denise; Romans, Brian W.; Varela Valenzuela, Natalia; Jones, Harold; Beny, Francois; Browne, Imogen; Cortese, Giuseppe; Sousa, Isobela M. C.; Dodd, Justin P.; Esper, Oliver M.; Gales, Jenny; Harwood, David; Ishino, Saki; Kim, Sookwan; Kim, Sunghan; Laberg, Jan S.; Leckie, R. Mark; Müller, Juliane; Shevenell, Amelia; Singh, Shiv; Sugisaki, Saiko T.; van de Flierdt, Tina; van Peer, Tim; Xiao, Wenshen; Xiong, Zhifang; De Santis, Laura; McKay, Robert</b> (2026). Spatially variable response of Antarctica’s ice sheets to orbital forcing during the Pliocene. <i>Nature Geoscience 19(2)</i>: 182-188. <a href=\"https://dx.doi.org/10.1038/s41561-025-01840-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01840-y</a>","StandardTitle":"Spatially variable response of Antarctica’s ice sheets to orbital forcing during the Pliocene","AuthorsString":"Patterson, Molly O. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":353951,"RR":"<b>Friedel, M.; Chiodo, G.; Stenke, A.; Domeisen, D.I.V.; Fueglistaler, S.; Anet, J.G.; Peter, T.</b> (2022). Springtime Arctic ozone depletion forces northern hemisphere climate anomalies. <i>Nature Geoscience 15(7)</i>: 541-547. <a href=\"https://dx.doi.org/10.1038/s41561-022-00974-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00974-7</a>","StandardTitle":"Springtime Arctic ozone depletion forces northern hemisphere climate anomalies","AuthorsString":"Friedel, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":248285,"RR":"<b>von Blanckenburg, F.; Bouchez, J.; Ibarra, D.E.; Maher, K.</b> (2015). Stable runoff and weathering fluxes into the oceans over Quaternary climate cycles. <i>Nature Geoscience 8(7)</i>: 538-542. <a href=\"http://dx.doi.org/10.1038/ngeo2452\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2452</a>","StandardTitle":"Stable runoff and weathering fluxes into the oceans over Quaternary climate cycles","AuthorsString":"von Blanckenburg, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392766,"RR":"<b>Zhou, W.; Leung, L.R.; Lu, J.</b> (2024). Steady threefold Arctic amplification of externally forced warming masked by natural variability. <i>Nature Geoscience 17(6)</i>: 508-515. <a href=\"https://dx.doi.org/10.1038/s41561-024-01441-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01441-1</a>","StandardTitle":"Steady threefold Arctic amplification of externally forced warming masked by natural variability","AuthorsString":"Zhou, W.; Leung, L.R.; Lu, J.","BibLvlCode":"AS"},{"BRefID":241879,"RR":"<b>Fagherazzi, S.</b> (2014). Storm-proofing with marshes. <i>Nature Geoscience 7(10)</i>: 701-702. <a href=\"http://dx.doi.org/10.1038/ngeo2262\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2262</a>","StandardTitle":"Storm-proofing with marshes","AuthorsString":"Fagherazzi, S.","BibLvlCode":"AS"},{"BRefID":349091,"RR":"<b>Green, A.N.; Cooper, J.A.G.; Loureiro, C.; Dixon, S.; Hahn, A.; Zabel, M.</b> (2022). Stormier mid-Holocene southwest Indian Ocean due to poleward trending tropical cyclones. <i>Nature Geoscience 15(1)</i>: 60-66. <a href=\"https://dx.doi.org/10.1038/s41561-021-00842-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00842-w</a>","StandardTitle":"Stormier mid-Holocene southwest Indian Ocean due to poleward trending tropical cyclones","AuthorsString":"Green, A.N. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":349092,"RR":"<b>Ulrich, T.; Gabriel, A.-A.; Madden, E.H.</b> (2022). Stress, rigidity and sediment strength control megathrust earthquake and tsunami dynamics. <i>Nature Geoscience 15(1)</i>: 67-73. <a href=\"https://dx.doi.org/10.1038/s41561-021-00863-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00863-5</a>","StandardTitle":"Stress, rigidity and sediment strength control megathrust earthquake and tsunami dynamics","AuthorsString":"Ulrich, T.; Gabriel, A.-A.; Madden, E.H.","BibLvlCode":"AS"},{"BRefID":408332,"RR":"<b>Peng, Q.; Xie, S.-P.; Miyamoto, A.; Deser, C.; Zhang, P.; Luongo, M.T.</b> (2025). Strong 2023–2024 El Niño generated by ocean dynamics. <i>Nature Geoscience 18(6)</i>: 471-478. <a href=\"https://dx.doi.org/10.1038/s41561-025-01700-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01700-9</a>","StandardTitle":"Strong 2023–2024 El Niño generated by ocean dynamics","AuthorsString":"Peng, Q. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":246327,"RR":"<b>Chen, D.; Lian, T.; Fu, C.; Cane, M.A.; Tang, Y.; Murtugudde, R.; Song, X.; Wu, Q.; Zhou, L.</b> (2015). Strong influence of westerly wind bursts on El Niño diversity. <i>Nature Geoscience 8(5)</i>: 339–345. <a href=\"http://dx.doi.org/10.1038/ngeo2399\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2399</a>","StandardTitle":"Strong influence of westerly wind bursts on El Niño diversity","AuthorsString":"Chen, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":371759,"RR":"<b>Jonkers, L.; Laepple, T.; Rillo, M.C.; Shi, X.; Dolman, A.M.; Lohmann, G.; Paul, A.; Mix, A.; Kucera, M.</b> (2023). Strong temperature gradients in the ice age North Atlantic Ocean revealed by plankton biogeography. <i>Nature Geoscience 16(12)</i>: 1114-1119. <a href=\"https://dx.doi.org/10.1038/s41561-023-01328-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01328-7</a>","StandardTitle":"Strong temperature gradients in the ice age North Atlantic Ocean revealed by plankton biogeography","AuthorsString":"Jonkers, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":248439,"RR":"<b>Jacobs, S.S.; Jenkins, A.; Giulivi, C.F.; Dutrieux, P.</b> (2011). Stronger ocean circulation and increased melting under Pine Island Glacier ice shelf. <i>Nature Geoscience 4(8)</i>: 519-523. <a href=\"http://dx.doi.org/10.1038/ngeo1188\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1188</a>","StandardTitle":"Stronger ocean circulation and increased melting under Pine Island Glacier ice shelf","AuthorsString":"Jacobs, S.S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":367911,"RR":"<b>Moreira, H.; Storey, C.; Bruand, E.; Darling, J.; Fowler, M.; Cotte, M.; Villalobos-Portillo, E.E.; Parat, F.; Seixas, L.; Philippot, P.; Dhuime, B.</b> (2023). Sub-arc mantle fugacity shifted by sediment recycling across the Great Oxidation Event. <i>Nature Geoscience 16(10)</i>: 922-927. <a href=\"https://dx.doi.org/10.1038/s41561-023-01258-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01258-4</a>","StandardTitle":"Sub-arc mantle fugacity shifted by sediment recycling across the Great Oxidation Event","AuthorsString":"Moreira, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396165,"RR":"<b>Angelopoulos, M.; Paull, C. K.</b> (2024). Subarctic permafrost formation around seafloor seeps. <i>Nature Geoscience 17(10)</i>: 956-957. <a href=\"https://dx.doi.org/10.1038/s41561-024-01549-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01549-4</a>","StandardTitle":"Subarctic permafrost formation around seafloor seeps","AuthorsString":"Angelopoulos, M.; Paull, C. K.","BibLvlCode":"AS"},{"BRefID":243208,"RR":"<b>Ague, J.J.</b> (2014). Subduction goes organic. <i>Nature Geoscience 7(12)</i>: 860–861. <a href=\"http://dx.doi.org/10.1038/ngeo2301\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2301</a>","StandardTitle":"Subduction goes organic","AuthorsString":"Ague, J.J.","BibLvlCode":"AS"},{"BRefID":324019,"RR":"<b>Kirkpatrick, J.D.; Edwards, J.H.; Verdecchia, A.; Kluesner, J.W.; Harrington, R.M.; Silver, E.A.</b> (2020). Subduction megathrust heterogeneity characterized from 3D seismic data. <i>Nature Geoscience 13(5)</i>: 369-374. <a href=\"https://dx.doi.org/10.1038/s41561-020-0562-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0562-9</a>","StandardTitle":"Subduction megathrust heterogeneity characterized from 3D seismic data","AuthorsString":"Kirkpatrick, J.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":368752,"RR":"(2023). Subglacial landscape in the Antarctic interior consistent with past fast ice flow. <i>Nature Geoscience 16(11)</i>: 946-947. <a href=\"https://dx.doi.org/10.1038/s41561-023-01267-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01267-3</a>","StandardTitle":"Subglacial landscape in the Antarctic interior consistent with past fast ice flow","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":254717,"RR":"<b>Ashmore, D.W.</b> (2016). Submarine Antarctic icescapes. <i>Nature Geoscience 9(4)</i>: 267-268. <a href=\"http://dx.doi.org/10.1038/ngeo2680\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2680</a>","StandardTitle":"Submarine Antarctic icescapes","AuthorsString":"Ashmore, D.W.","BibLvlCode":"AS"},{"BRefID":341634,"RR":"<b>Normandeau, A.; MacKillop, K.; Macquarrie, M.; Richards, C.; Bourgault, D.; Campbell, D.C.; Maselli, V.; Philibert, G.; Clarke, J.H.</b> (2021). Submarine landslides triggered by iceberg collision with the seafloor. <i>Nature Geoscience 14(8)</i>: 599-605. <a href=\"https://dx.doi.org/10.1038/s41561-021-00767-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00767-4</a>","StandardTitle":"Submarine landslides triggered by iceberg collision with the seafloor","AuthorsString":"Normandeau, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":356599,"RR":"<b>Slater, D.A.; Straneo, F.</b> (2022). Submarine melting of glaciers in Greenland amplified by atmospheric warming. <i>Nature Geoscience 15(10)</i>: 794-799. <a href=\"https://dx.doi.org/10.1038/s41561-022-01035-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01035-9</a>","StandardTitle":"Submarine melting of glaciers in Greenland amplified by atmospheric warming","AuthorsString":"Slater, D.A.; Straneo, F.","BibLvlCode":"AS"},{"BRefID":436563,"RR":"<b>McCaig, A.</b> (2025). Submarine talus may contribute to climate cooling. <i>Nature Geoscience 18(12)</i>: 1187-1188. <a href=\"https://dx.doi.org/10.1038/s41561-025-01824-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01824-y</a>","StandardTitle":"Submarine talus may contribute to climate cooling","AuthorsString":"McCaig, A.","BibLvlCode":"AS"},{"BRefID":364410,"RR":"<b>Gilchrist, J.T.; Jellinek, A.M.; Hooft, E.E.E.; Wanket, S.</b> (2023). Submarine terraced deposits linked to periodic collapse of caldera-forming eruption columns. <i>Nature Geoscience 16(5)</i>: 446-453. <a href=\"https://dx.doi.org/10.1038/s41561-023-01160-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01160-z</a>","StandardTitle":"Submarine terraced deposits linked to periodic collapse of caldera-forming eruption columns","AuthorsString":"Gilchrist, J.T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":216512,"RR":"<b>Mitchell, N.</b> (2012). Submarine volcanism: Hot, cracking rocks deep down. <i>Nature Geoscience 5(7)</i>: 444-445. <a href=\"http://dx.doi.org/10.1038/ngeo1505\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo1505</a>","StandardTitle":"Submarine volcanism: Hot, cracking rocks deep down","AuthorsString":"Mitchell, N.","BibLvlCode":"AS"},{"BRefID":283769,"RR":"<b>Hannington, M.D.; Petersen, S.; Krätschell, A.</b> (2017). Subsea mining moves closer to shore. <i>Nature Geoscience 10(3)</i>: 158-159. <a href=\"http://dx.doi.org/10.1038/ngeo2897\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2897</a>","StandardTitle":"Subsea mining moves closer to shore","AuthorsString":"Hannington, M.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":419028,"RR":"<b>Jolivet, R.</b> (2025). Subsidence signals unexpected seismic and tsunami hazard. <i>Nature Geoscience 18(10)</i>: 938-939. <a href=\"https://dx.doi.org/10.1038/s41561-025-01809-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01809-x</a>","StandardTitle":"Subsidence signals unexpected seismic and tsunami hazard","AuthorsString":"Jolivet, R.","BibLvlCode":"AS"},{"BRefID":337183,"RR":"<b>Fan, J.; Zhao, D.</b> (2021). Subslab heterogeneity and giant megathrust earthquakes. <i>Nature Geoscience 14(5)</i>: 349-353. <a href=\"https://hdl.handle.net/10.1038/s41561-021-00728-x\" target=\"_blank\">https://hdl.handle.net/10.1038/s41561-021-00728-x</a>","StandardTitle":"Subslab heterogeneity and giant megathrust earthquakes","AuthorsString":"Fan, J.; Zhao, D.","BibLvlCode":"AS"},{"BRefID":356602,"RR":"<b>Benavent, Nuria; Mahajan, Anoop S.; Li, Qinyi; Cuevas, Carlos A.; Schmale, Julia; Angot, Hélène; Jokinen, Tuija; Quéléver, Lauriane L. J.; Blechschmidt, Anne-Marlene; Zilker, Bianca; Richter, Andreas; Serna, Jesús A.; Garcia-Nieto, David; Fernandez, Rafael P.; Skov, Henrik; Dumitrascu, Adela; Simões Pereira, Patric; Abrahamsson, Katarina; Bucci, Silvia; Duetsch, Marina; Stohl, Andreas; Beck, Ivo; Laurila, Tiia; Blomquist, Byron; Howard, Dean; Archer, Stephen D.; Bariteau, Ludovic; Helmig, Detlev; Hueber, Jacques; Jacobi, Hans-Werner; Posman, Kevin; Dada, Lubna; Daellenbach, Kaspar R.; Saiz-Lopez, Alfonso</b> (2022). Substantial contribution of iodine to Arctic ozone destruction. <i>Nature Geoscience 15(10)</i>: 770-773. <a href=\"https://dx.doi.org/10.1038/s41561-022-01018-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01018-w</a>","StandardTitle":"Substantial contribution of iodine to Arctic ozone destruction","AuthorsString":"Benavent, Nuria <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":393298,"RR":"<b>Dell, R.L.; Willis, I.C.; Arnold, N.S.; Banwell, A.F.; de Roda Husman, S.</b> (2024). Substantial contribution of slush to meltwater area across Antarctic ice shelves. <i>Nature Geoscience 17(7)</i>: 624-630. <a href=\"https://dx.doi.org/10.1038/s41561-024-01466-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01466-6</a>","StandardTitle":"Substantial contribution of slush to meltwater area across Antarctic ice shelves","AuthorsString":"Dell, R.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392280,"RR":"<b>Chen, Y.; Haywood, J.; Wang, Y.; Malavelle, F.; Jordan, G.; Peace, A.; Partridge, D.G.; Cho, N.; Oreopoulos, L.; Grosvenor, D.; Field, P.; Allan, R.P.; Lohmann, U.</b> (2024). Substantial cooling effect from aerosol-induced increase in tropical marine cloud cover. <i>Nature Geoscience 17(5)</i>: 404-410. <a href=\"https://dx.doi.org/10.1038/s41561-024-01427-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01427-z</a>","StandardTitle":"Substantial cooling effect from aerosol-induced increase in tropical marine cloud cover","AuthorsString":"Chen, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":290728,"RR":"<b>Overeem, I.; Hudson, B.D.; Syvitski, J.P.M.; Mikkelsen, A.B.; van den Broeke, M.R.; Noël, B.P.Y.; Morlighem, M.</b> (2017). Substantial export of suspended sediment to the global oceans from glacial erosion in Greenland. <i>Nature Geoscience 10(11)</i>: 859-863. <a href=\"https://dx.doi.org/10.1038/ngeo3046\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3046</a>","StandardTitle":"Substantial export of suspended sediment to the global oceans from glacial erosion in Greenland","AuthorsString":"Overeem, I. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":356603,"RR":"<b>Yang, D.; Zhou, W.; Seidel, S.D.</b> (2022). Substantial influence of vapour buoyancy on tropospheric air temperature and subtropical cloud. <i>Nature Geoscience 15(10)</i>: 781-788. <a href=\"https://dx.doi.org/10.1038/s41561-022-01033-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01033-x</a>","StandardTitle":"Substantial influence of vapour buoyancy on tropospheric air temperature and subtropical cloud","AuthorsString":"Yang, D.; Zhou, W.; Seidel, S.D.","BibLvlCode":"AS"},{"BRefID":286595,"RR":"<b>Li, Y.; Zhang, C.; Wang, N.; Han, Q.; Zhang, X.; Liu, Y.; Xu, L.; Ye, W.</b> (2017). Substantial inorganic carbon sink in closed drainage basins globally. <i>Nature Geoscience 10(7)</i>: 501-506. <a href=\"https://dx.doi.org/10.1038/ngeo2972\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2972</a>","StandardTitle":"Substantial inorganic carbon sink in closed drainage basins globally","AuthorsString":"Li, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":250812,"RR":"<b>Baldermann, A.; Warr, L.N.; Letofsky-Papst, I.; Mavromatis, V.</b> (2015). Substantial iron sequestration during green-clay authigenesis in modern deep-sea sediments. <i>Nature Geoscience 8(11)</i>: 885–889. <a href=\"http://dx.doi.org/10.1038/ngeo2542\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2542</a>","StandardTitle":"Substantial iron sequestration during green-clay authigenesis in modern deep-sea sediments","AuthorsString":"Baldermann, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291795,"RR":"<b>Scott, C.E.; Arnold, S.R.; Monks, S.A.; Asmi, A.; Paasonen, P.; Spracklen, D.V.</b> (2018). Substantial large-scale feedbacks between natural aerosols and climate. <i>Nature Geoscience 11(1)</i>: 44-48. <a href=\"https://dx.doi.org/10.1038/s41561-017-0020-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0020-5</a>","StandardTitle":"Substantial large-scale feedbacks between natural aerosols and climate","AuthorsString":"Scott, C.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":281129,"RR":"<b>Krause-Jensen, D.; Duarte, C.M.</b> (2016). Substantial role of macroalgae in marine carbon sequestration. <i>Nature Geoscience 9(10)</i>: 737-742. <a href=\"http://dx.doi.org/10.1038/ngeo2790\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2790</a>","StandardTitle":"Substantial role of macroalgae in marine carbon sequestration","AuthorsString":"Krause-Jensen, D.; Duarte, C.M.","BibLvlCode":"AS"},{"BRefID":312027,"RR":"<b>Slater, S.M.; Twitchett, R.J.; Danise, S.; Vajda, V.</b> (2019). Substantial vegetation response to Early Jurassic global warming with impacts on oceanic anoxia. <i>Nature Geoscience 12(6)</i>: 462-467. <a href=\"https://dx.doi.org/10.1038/s41561-019-0349-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0349-z</a>","StandardTitle":"Substantial vegetation response to Early Jurassic global warming with impacts on oceanic anoxia","AuthorsString":"Slater, S.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291796,"RR":"<b>Moon, T.; Sutherland, D.A.; Carroll, D.; Felikson, D.; Kehrl, L.; Straneo, F.</b> (2017). Subsurface iceberg melt key to Greenland fjord freshwater budget. <i>Nature Geoscience 11(1)</i>: 49-54. <a href=\"https://dx.doi.org/10.1038/s41561-017-0018-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0018-z</a>","StandardTitle":"Subsurface iceberg melt key to Greenland fjord freshwater budget","AuthorsString":"Moon, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":242737,"RR":"<b>Hill, J.C.; Condron, A.</b> (2014). Subtropical iceberg scours and meltwater routing in the deglacial western North Atlantic. <i>Nature Geoscience 7(11)</i>: 806–810. <a href=\"http://dx.doi.org/10.1038/ngeo2267\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2267</a>","StandardTitle":"Subtropical iceberg scours and meltwater routing in the deglacial western North Atlantic","AuthorsString":"Hill, J.C.; Condron, A.","BibLvlCode":"AS"},{"BRefID":247381,"RR":"<b>Alexander, K.; Meissner, K.J.; Bralower, T.J.</b> (2015). Sudden spreading of corrosive bottom water during the Palaeocene–Eocene Thermal Maximum. <i>Nature Geoscience 8(6)</i>: 458–461. <a href=\"http://dx.doi.org/10.1038/ngeo2430\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2430</a>","StandardTitle":"Sudden spreading of corrosive bottom water during the Palaeocene–Eocene Thermal Maximum","AuthorsString":"Alexander, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":419027,"RR":"<b>Bataille, C.P.; Skierszkan, E.K.</b> (2025). Sulfur cycling in thawing permafrost landscapes. <i>Nature Geoscience 18(10)</i>: 936-937. <a href=\"https://dx.doi.org/10.1038/s41561-025-01804-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01804-2</a>","StandardTitle":"Sulfur cycling in thawing permafrost landscapes","AuthorsString":"Bataille, C.P.; Skierszkan, E.K.","BibLvlCode":"AS"},{"BRefID":396169,"RR":"<b>Webster, M.A.; Riihelä, A.; Kacimi, S.; Ballinger, T.J.; Blanchard-Wrigglesworth, E.; Parker, C.L.; Boisvert, L.</b> (2024). Summer snow on Arctic sea ice modulated by the Arctic Oscillation. <i>Nature Geoscience 17(10)</i>: 995-1002. <a href=\"https://dx.doi.org/10.1038/s41561-024-01525-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01525-y</a>","StandardTitle":"Summer snow on Arctic sea ice modulated by the Arctic Oscillation","AuthorsString":"Webster, M.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":334829,"RR":"<b>Hou, M.; He, Y.; Jang, B.G.; Sun, S.; Zhuang, Y.; Deng, L.; Tang, R.; Chen, J.; Ke, F.; Meng, Y.; Prakapenka, V.B.; Chen, B.; Shim, J.H.; Liu, J.; Kim, D.Y.; Hu, Q.; Pickard, C.J.; Needs, R.J.; Mao, H.-K.</b> (2021). Superionic iron oxide–hydroxide in Earth’s deep mantle. <i>Nature Geoscience 14(3)</i>: 174-178. <a href=\"https://dx.doi.org/10.1038/s41561-021-00696-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00696-2</a>","StandardTitle":"Superionic iron oxide–hydroxide in Earth’s deep mantle","AuthorsString":"Hou, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":308734,"RR":"<b>Mai, P.M.</b> (2019). Supershear tsunami disaster. <i>Nature Geoscience 12(3)</i>: 150-151. <a href=\"https://dx.doi.org/10.1038/s41561-019-0308-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0308-8</a>","StandardTitle":"Supershear tsunami disaster","AuthorsString":"Mai, P.M.","BibLvlCode":"AS"},{"BRefID":281762,"RR":"<b>White, N.</b> (2016). Surface sculpting by hidden agents. <i>Nature Geoscience 9(12)</i>: 867-869. <a href=\"http://dx.doi.org/10.1038/ngeo2842\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2842</a>","StandardTitle":"Surface sculpting by hidden agents","AuthorsString":"White, N.","BibLvlCode":"AS"},{"BRefID":363730,"RR":"<b>Allen, R.J.; Zhao, X.; Randles, C.A.; Kramer, R.J.; Samset, B.H.; Smith, C.J.</b> (2023). Surface warming and wetting due to methane’s long-wave radiative effects muted by short-wave absorption. <i>Nature Geoscience 16(4)</i>: 314-320. <a href=\"https://dx.doi.org/10.1038/s41561-023-01144-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01144-z</a>","StandardTitle":"Surface warming and wetting due to methane’s long-wave radiative effects muted by short-wave absorption","AuthorsString":"Allen, R.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":408331,"RR":"<b>Wang, D.; Ma, H.; Li, X.; Hu, Y.; Hu, Z.; Liu, C.; Ding, M.; Li, C.; Jiang, S.; Liu, Y.; Lu, S.; Sun, B.; Zeng, G.; Van den Broeke, M.; Shi, G.</b> (2025). Sustained decrease in inland East Antarctic surface mass balance between 2005 and 2020. <i>Nature Geoscience 18(6)</i>: 462-470. <a href=\"https://dx.doi.org/10.1038/s41561-025-01699-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01699-z</a>","StandardTitle":"Sustained decrease in inland East Antarctic surface mass balance between 2005 and 2020","AuthorsString":"Wang, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396658,"RR":"<b>Roland, T.P.; Bartlett, O.T.; Charman, D.J.; Anderson, K.; Hodgson, D.A.; Amesbury, M.J.; Maclean, I.; Fretwell, P.T.; Fleming, A.</b> (2024). Sustained greening of the Antarctic Peninsula observed from satellites. <i>Nature Geoscience 17(11)</i>: 1121-1126. <a href=\"https://dx.doi.org/10.1038/s41561-024-01564-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01564-5</a>","StandardTitle":"Sustained greening of the Antarctic Peninsula observed from satellites","AuthorsString":"Roland, T.P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":393307,"RR":"<b>Stockey, Richard G.; Cole, Devon B.; Farrell, Una C.; Agić, Heda; Boag, Thomas H.; Brocks, Jochen J.; Canfield, Don E.; Cheng, Meng; Crockford, Peter W.; Cui, Huan; Dahl, Tais W.; Del Mouro, Lucas; Dewing, Keith; Dornbos, Stephen Q.; Emmings, Joseph F.; Gaines, Robert R.; Gibson, Timothy M.; Gill, Benjamin C.; Gilleaudeau, Geoffrey J.; Goldberg, Karin; Guilbaud, Romain; Halverson, Galen; Hammarlund, Emma U.; Hantsoo, Kalev; Henderson, Miles A.; Henderson, Charles M.; Hodgskiss, Malcolm S. W.; Jarrett, Amber J. M.; Johnston, David T.; Kabanov, Pavel; Kimmig, Julien; Knoll, Andrew H.; Kunzmann, Marcus; LeRoy, Matthew A.; Li, Chao; Loydell, David K.; Macdonald, Francis A.; Magnall, Joseph M.; Mills, N. Tanner; Och, Lawrence M.; O’Connell, Brennan; Pagès, Anais; Peters, Shanan E.; Porter, Susannah M.; Poulton, Simon W.; Ritzer, Samantha R.; Rooney, Alan D.; Schoepfer, Shane; Smith, Emily F.; Strauss, Justin V.; Uhlein, Gabriel Jubé; White, Tristan; Wood, Rachel A.; Woltz, Christina R.; Yurchenko, Inessa; Planavsky, Noah J.; Sperling, Erik A.</b> (2024). Sustained increases in atmospheric oxygen and marine productivity in the Neoproterozoic and Palaeozoic eras. <i>Nature Geoscience 17(7)</i>: 667-674. <a href=\"https://dx.doi.org/10.1038/s41561-024-01479-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01479-1</a>","StandardTitle":"Sustained increases in atmospheric oxygen and marine productivity in the Neoproterozoic and Palaeozoic eras","AuthorsString":"Stockey, Richard G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":354973,"RR":"<b>Ford, H.L.; Burls, N.J.; Jacobs, P; Jahn, A.; Caballero-Gill, R.P.; Hodell, D.A.; Fedorov, A.V.</b> (2022). Sustained mid-Pliocene warmth led to deep water formation in the North Pacific. <i>Nature Geoscience 15(8)</i>: 658-663. <a href=\"https://dx.doi.org/10.1038/s41561-022-00978-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00978-3</a>","StandardTitle":"Sustained mid-Pliocene warmth led to deep water formation in the North Pacific","AuthorsString":"Ford, H.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":437763,"RR":"<b>Toucanne, S.; Vazquez Riveiros, N.; Soulet, G.; Blard, P.-H.; Migeon, A.; Rigalleau, V.; Roubi, A.; Cheron, S.; Boissier, A.; Menviel, L.; Bostock, H.</b> (2026). Synchronous bipolar retreat of mid-latitude ice masses during Heinrich Stadials. <i>Nature Geoscience 19(2)</i>: 195-200. <a href=\"https://dx.doi.org/10.1038/s41561-025-01887-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01887-x</a>","StandardTitle":"Synchronous bipolar retreat of mid-latitude ice masses during Heinrich Stadials","AuthorsString":"Toucanne, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":303727,"RR":"<b>Black, B.A.; Neely, R.R.; Lamarque, J.-F.; Elkins-Tanton, L.T.; Kiehl, J.T.; Shields, C.A.; Mills, M.J.; Bardeen, C.</b> (2018). Systemic swings in end-Permian climate from Siberian Traps carbon and sulfur outgassing. <i>Nature Geoscience 11(12)</i>: 949-954. <a href=\"https://dx.doi.org/10.1038/s41561-018-0261-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0261-y</a>","StandardTitle":"Systemic swings in end-Permian climate from Siberian Traps carbon and sulfur outgassing","AuthorsString":"Black, B.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":241878,"RR":"<b>Etourneau, J.</b> (2014). Tectonically driven upwelling. <i>Nature Geoscience 7(10)</i>: 698-699. <a href=\"http://dx.doi.org/10.1038/ngeo2261\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2261</a>","StandardTitle":"Tectonically driven upwelling","AuthorsString":"Etourneau, J.","BibLvlCode":"AS"},{"BRefID":286594,"RR":"<b>Coats, S.; Smerdon, J.E.</b> (2017). The Atlantic's internal drum beat. <i>Nature Geoscience 10(7)</i>: 470-471. <a href=\"https://dx.doi.org/10.1038/ngeo2970\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2970</a>","StandardTitle":"The Atlantic's internal drum beat","AuthorsString":"Coats, S.; Smerdon, J.E.","BibLvlCode":"AS"},{"BRefID":347898,"RR":"<b>Leonardi, N.</b> (2021). The barriers of Venice. <i>Nature Geoscience 14(12)</i>: 881-882. <a href=\"https://dx.doi.org/10.1038/s41561-021-00864-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00864-4</a>","StandardTitle":"The barriers of Venice","AuthorsString":"Leonardi, N.","BibLvlCode":"AS"},{"BRefID":359511,"RR":"<b>John, S.G.; Kelly, R.L.; Bian, X.; Fu, F.; Smith, M.I.; Lanning, N.T.; Liang, H.; Pasquier, B.; Seelen, E.A.; Holzer, M.; Wasylenki, L.; Conway, T.M.; Fitzsimmons, J.N.; Hutchins, D.A.; Yang, S.-C.</b> (2022). The biogeochemical balance of oceanic nickel cycling. <i>Nature Geoscience 15(11)</i>: 906-912. <a href=\"https://dx.doi.org/10.1038/s41561-022-01045-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01045-7</a>","StandardTitle":"The biogeochemical balance of oceanic nickel cycling","AuthorsString":"John, S.G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":324988,"RR":"<b>Li, Y.; Vocadlo, L.; Sun, T.; Brodholt, J.P.</b> (2020). The Earth’s core as a reservoir of water. <i>Nature Geoscience 13(6)</i>: 453-458. <a href=\"https://dx.doi.org/10.1038/s41561-020-0578-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0578-1</a>","StandardTitle":"The Earth’s core as a reservoir of water","AuthorsString":"Li, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":243210,"RR":"<b>Planavsky, N.J.</b> (2014). The elements of marine life. <i>Nature Geoscience 7(12)</i>: 855-856. <a href=\"http://dx.doi.org/10.1038/ngeo2307\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2307</a>","StandardTitle":"The elements of marine life","AuthorsString":"Planavsky, N.J.","BibLvlCode":"AS"},{"BRefID":334820,"RR":"<b>Ozaki, K.; Reinhard, C.T.</b> (2021). The future lifespan of Earth’s oxygenated atmosphere. <i>Nature Geoscience 14(3)</i>: 138-142. <a href=\"https://dx.doi.org/10.1038/s41561-021-00693-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00693-5</a>","StandardTitle":"The future lifespan of Earth’s oxygenated atmosphere","AuthorsString":"Ozaki, K.; Reinhard, C.T.","BibLvlCode":"AS"},{"BRefID":306493,"RR":"<b>McGuire, J.J.</b> (2019). The geology of earthquake swarms. <i>Nature Geoscience 12(2)</i>: 82-83. <a href=\"https://dx.doi.org/10.1038/s41561-019-0302-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0302-1</a>","StandardTitle":"The geology of earthquake swarms","AuthorsString":"McGuire, J.J.","BibLvlCode":"AS"},{"BRefID":419026,"RR":"<b>Mottram, R.; Hansen, N.; Hogg, A.E.; Rodehacke, C.B.; Simonsen, S.B.; Wallis, B.J.</b> (2025). The Greenlandification of Antarctica. <i>Nature Geoscience 18(10)</i>: 928-930. <a href=\"https://dx.doi.org/10.1038/s41561-025-01805-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01805-1</a>","StandardTitle":"The Greenlandification of Antarctica","AuthorsString":"Mottram, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":238942,"RR":"<b>Scholz, F.; McManus, J.; Mix, A.C.; Hensen, C.; Schneider, R.</b> (2014). The impact of ocean deoxygenation on iron release from continental margin sediments. <i>Nature Geoscience 7(6)</i>: 433–437. <a href=\"http://dx.doi.org/10.1038/ngeo2162\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2162</a>","StandardTitle":"The impact of ocean deoxygenation on iron release from continental margin sediments","AuthorsString":"Scholz, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":352880,"RR":"<b>Lofverstrom, M.; Thompson, D.M.; Otto-Bliesner, B.L.; Brady, E.C.</b> (2022). The importance of Canadian Arctic Archipelago gateways for glacial expansion in Scandinavia. <i>Nature Geoscience 15(6)</i>: 482-488. <a href=\"https://dx.doi.org/10.1038/s41561-022-00956-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00956-9</a>","StandardTitle":"The importance of Canadian Arctic Archipelago gateways for glacial expansion in Scandinavia","AuthorsString":"Lofverstrom, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":239611,"RR":"<b>Sprintall, J.; Gordon, A.L.; Koch-Larrouy, A.; Lee, T.; Potemra, J.T.; Pujiana, K.; Wijffels, S.E.</b> (2014). The Indonesian seas and their role in the coupled ocean–climate system. <i>Nature Geoscience 7(7)</i>: 487-492. <a href=\"http://dx.doi.org/10.1038/ngeo2188\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2188</a>","StandardTitle":"The Indonesian seas and their role in the coupled ocean–climate system","AuthorsString":"Sprintall, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":320529,"RR":"<b>Ray, E.A.; Portmann, R.W.; Yu, P.; Daniel, J.; Montzka, S.A.; Dutton, G.S.; Hall, B.D.; Moore, F.L.; Rosenlof, K.H.</b> (2020). The influence of the stratospheric Quasi-Biennial Oscillation on trace gas levels at the Earth’s surface. <i>Nature Geoscience 13(1)</i>: 22-27. <a href=\"https://dx.doi.org/10.1038/s41561-019-0507-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0507-3</a>","StandardTitle":"The influence of the stratospheric Quasi-Biennial Oscillation on trace gas levels at the Earth’s surface","AuthorsString":"Ray, E.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":330716,"RR":"<b>Brenan, J.M.</b> (2020). The magmatic forge. <i>Nature Geoscience 13(11)</i>: 716-717. <a href=\"https://dx.doi.org/10.1038/s41561-020-0644-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0644-8</a>","StandardTitle":"The magmatic forge","AuthorsString":"Brenan, J.M.","BibLvlCode":"AS"},{"BRefID":406638,"RR":"<b>Sun, Z.; Xu, Y.; Deng, Y.</b> (2025). The Moho is in reach of ocean drilling with the <i>Meng Xiang</i>. <i>Nature Geoscience 18(4)</i>: 275-276. <a href=\"https://dx.doi.org/10.1038/s41561-025-01675-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01675-7</a>","StandardTitle":"The Moho is in reach of ocean drilling with the <i>Meng Xiang</i>","AuthorsString":"Sun, Z.; Xu, Y.; Deng, Y.","BibLvlCode":"AS"},{"BRefID":259364,"RR":"<b>Delworth, T.L.; Zeng, F.; Vecchi, G.A.; Yang, X.; Zhang, L.; Zhang, R.</b> (2016). The North Atlantic Oscillation as a driver of rapid climate change in the Northern Hemisphere. <i>Nature Geoscience 9(7)</i>: 509-512. <a href=\"http://dx.doi.org/10.1038/ngeo2738\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2738</a>","StandardTitle":"The North Atlantic Oscillation as a driver of rapid climate change in the Northern Hemisphere","AuthorsString":"Delworth, T.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":250814,"RR":"<b>Beaupré, S.R.</b> (2015). The ocean's pressure cooker. <i>Nature Geoscience 8(11)</i>: 820-821. <a href=\"http://dx.doi.org/10.1038/ngeo2562\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2562</a>","StandardTitle":"The ocean's pressure cooker","AuthorsString":"Beaupré, S.R.","BibLvlCode":"AS"},{"BRefID":395750,"RR":"<b>van Wijk, J.</b> (2024). The oldest parts of continents are falling apart. <i>Nature Geoscience 17(9)</i>: 820-821. <a href=\"https://dx.doi.org/10.1038/s41561-024-01528-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01528-9</a>","StandardTitle":"The oldest parts of continents are falling apart","AuthorsString":"van Wijk, J.","BibLvlCode":"AS"},{"BRefID":245582,"RR":"<b>Markus, T.; Huhn, K.; Bischof, K.</b> (2015). The quest for sea-floor integrity. <i>Nature Geoscience 8(3)</i>: 163-164. <a href=\"http://dx.doi.org/10.1038/ngeo2380\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2380</a>","StandardTitle":"The quest for sea-floor integrity","AuthorsString":"Markus, T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":248279,"RR":"<b>Meltzner, A.J.</b> (2015). The rise and fall of an island. <i>Nature Geoscience 8(7)</i>: 501–502. <a href=\"http://dx.doi.org/10.1038/ngeo2477\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2477</a>","StandardTitle":"The rise and fall of an island","AuthorsString":"Meltzner, A.J.","BibLvlCode":"AS"},{"BRefID":238941,"RR":"<b>Crespo-Medina, M.; Meile, C.D.; Hunter, K.S.; Diercks, A.-R.; Asper, V.L.; Orphan, V.J.; Tavormina, P.L.; Nigro, L.M.; Battles, J.J.; Chanton, J.P.; Shiller, A.M.; Joung, D.-J.; Amon, R.M.W.; Bracco, A.; Montoya, J.P.; Villareal, T.A.; Wood, A.M.; Joye, S.B.</b> (2014). The rise and fall of methanotrophy following a deepwater oil-well blowout. <i>Nature Geoscience 7(6)</i>: 423–427. <a href=\"http://dx.doi.org/10.1038/ngeo2156\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2156</a>","StandardTitle":"The rise and fall of methanotrophy following a deepwater oil-well blowout","AuthorsString":"Crespo-Medina, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296636,"RR":"<b>Keane, J.T.</b> (2018). The rise and fall of the Great Barrier Reef. <i>Nature Geoscience 11(6)</i>: 388-388. <a href=\"https://dx.doi.org/10.1038/s41561-018-0154-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0154-0</a>","StandardTitle":"The rise and fall of the Great Barrier Reef","AuthorsString":"Keane, J.T.","BibLvlCode":"AS"},{"BRefID":436570,"RR":"<b>Boden, J.S.; Ostrander, C.M.; Stüeken, E.E.</b> (2025). The rise of free oxygen may have initiated on marine mud. <i>Nature Geoscience 18(12)</i>: 1202-1208. <a href=\"https://dx.doi.org/10.1038/s41561-025-01867-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01867-1</a>","StandardTitle":"The rise of free oxygen may have initiated on marine mud","AuthorsString":"Boden, J.S.; Ostrander, C.M.; Stüeken, E.E.","BibLvlCode":"AS"},{"BRefID":324989,"RR":"(2020). The rise of ocean robots. <i>Nature Geoscience 13(6)</i>: 393-393. <a href=\"https://dx.doi.org/10.1038/s41561-020-0597-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0597-y</a>","StandardTitle":"The rise of ocean robots","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":303663,"RR":"<b>Boudreau, B.P.; Middelburg, J.J.; Luo, Y.</b> (2018). The role of calcification in carbonate compensation. <i>Nature Geoscience 11(12)</i>: 894-900. <a href=\"https://dx.doi.org/10.1038/s41561-018-0259-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0259-5</a>","StandardTitle":"The role of calcification in carbonate compensation","AuthorsString":"Boudreau, B.P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":331730,"RR":"<b>Fakhraee, M.; Planavsky, N.J.; Reinhard, C.T.</b> (2020). The role of environmental factors in the long-term evolution of the marine biological pump. <i>Nature Geoscience 13(12)</i>: 812-816. <a href=\"https://dx.doi.org/10.1038/s41561-020-00660-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00660-6</a>","StandardTitle":"The role of environmental factors in the long-term evolution of the marine biological pump","AuthorsString":"Fakhraee, M.; Planavsky, N.J.; Reinhard, C.T.","BibLvlCode":"AS"},{"BRefID":341600,"RR":"<b>Staniec, A.; Vlahos, P.; Monahan, E.C.</b> (2021). The role of sea spray in atmosphere–ocean gas exchange. <i>Nature Geoscience 14(8)</i>: 593-598. <a href=\"https://dx.doi.org/10.1038/s41561-021-00796-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00796-z</a>","StandardTitle":"The role of sea spray in atmosphere–ocean gas exchange","AuthorsString":"Staniec, A.; Vlahos, P.; Monahan, E.C.","BibLvlCode":"AS"},{"BRefID":286599,"RR":"<b>Matzen, A.K.; Wood, B.J.; Baker, M.B.; Stolper, E.M.</b> (2017). The roles of pyroxenite and peridotite in the mantle sources of oceanic basalts. <i>Nature Geoscience 10(7)</i>: 530-535. <a href=\"https://dx.doi.org/10.1038/ngeo2968\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2968</a>","StandardTitle":"The roles of pyroxenite and peridotite in the mantle sources of oceanic basalts","AuthorsString":"Matzen, A.K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":324015,"RR":"<b>Ikari, M.J.</b> (2020). The rough ride of subducting fault surfaces. <i>Nature Geoscience 13(5)</i>: 329-330. <a href=\"https://dx.doi.org/10.1038/s41561-020-0574-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0574-5</a>","StandardTitle":"The rough ride of subducting fault surfaces","AuthorsString":"Ikari, M.J.","BibLvlCode":"AS"},{"BRefID":233936,"RR":"<b>Stickley, C.E.</b> (2014). The sea ice thickens. <i>Nature Geoscience 7(3)</i>: 165-166. <a href=\"http://dx.doi.org/10.1038/ngeo2080\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2080</a>","StandardTitle":"The sea ice thickens","AuthorsString":"Stickley, C.E.","BibLvlCode":"AS"},{"BRefID":368750,"RR":"(2023). The Shatsky Rise oceanic plateau formed through plume–ridge interaction. <i>Nature Geoscience 16(11)</i>: 944-945. <a href=\"https://dx.doi.org/10.1038/s41561-023-01289-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01289-x</a>","StandardTitle":"The Shatsky Rise oceanic plateau formed through plume–ridge interaction","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":296112,"RR":"<b>Renssen, H.; Seppä, H.; Heiri, O.; Roche, D.M.; Goosse, H.; Fichefet, T.</b> (2009). The spatial and temporal complexity of the Holocene thermal maximum. <i>Nature Geoscience 2(6)</i>: 410-413. <a href=\"https://dx.doi.org/10.1038/NGEO513\" target=\"_blank\">https://dx.doi.org/10.1038/NGEO513</a>","StandardTitle":"The spatial and temporal complexity of the Holocene thermal maximum","AuthorsString":"Renssen, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":329215,"RR":"<b>Herreid, S.; Pellicciotti, F.</b> (2020). The state of rock debris covering Earth’s glaciers. <i>Nature Geoscience 13(9)</i>: 621-627. <a href=\"https://dx.doi.org/10.1038/s41561-020-0615-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0615-0</a>","StandardTitle":"The state of rock debris covering Earth’s glaciers","AuthorsString":"Herreid, S.; Pellicciotti, F.","BibLvlCode":"AS"},{"BRefID":330718,"RR":"<b>Scown, M.W.</b> (2020). The sustainable development goals need geoscience. <i>Nature Geoscience 13(11)</i>: 714-715. <a href=\"https://dx.doi.org/10.1038/s41561-020-00652-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-00652-6</a>","StandardTitle":"The sustainable development goals need geoscience","AuthorsString":"Scown, M.W.","BibLvlCode":"AS"},{"BRefID":261251,"RR":"<b>Kosaka, Y.; Xie, S.-P.</b> (2016). The tropical Pacific as a key pacemaker of the variable rates of global warming. <i>Nature Geoscience 9(9)</i>: 669-673. <a href=\"http://dx.doi.org/10.1038/ngeo2770\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2770</a>","StandardTitle":"The tropical Pacific as a key pacemaker of the variable rates of global warming","AuthorsString":"Kosaka, Y.; Xie, S.-P.","BibLvlCode":"AS"},{"BRefID":211506,"RR":"<b>Plank, T.; van Keken, P.E.</b> (2008). The ups and downs of sediments. <i>Nature Geoscience 1(1)</i>: 17-18. <a href=\"http://dx.doi.org/10.1038/ngeo.2007.68\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo.2007.68</a>","StandardTitle":"The ups and downs of sediments","AuthorsString":"Plank, T.; van Keken, P.E.","BibLvlCode":"AS"},{"BRefID":404825,"RR":"<b>Harper, D.T.; Lam, A.R.; Penman, D.; Frieling, J.; Varela, N.; Chatterjee, S.</b> (2024). The value of scientific ocean drilling for early career researchers. <i>Nature Geoscience 17(12)</i>: 1184-1184. <a href=\"https://dx.doi.org/10.1038/s41561-024-01605-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01605-z</a>","StandardTitle":"The value of scientific ocean drilling for early career researchers","AuthorsString":"Harper, D.T. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396653,"RR":"<b>Byrne, Michael P.; Hegerl, Gabriele C.; Scheff, Jacob; Adam, Ori; Berg, Alexis; Biasutti, Michela; Bordoni, Simona; Dai, Aiguo; Geen, Ruth; Henry, Matthew; Hill, Spencer A.; Hohenegger, Cathy; Humphrey, Vincent; Joshi, Manoj; Konings, Alexandra G.; Laguë, Marysa M.; Lambert, F. Hugo; Lehner, Flavio; Mankin, Justin S.; McColl, Kaighin A.; McKinnon, Karen A.; Pendergrass, Angeline G.; Pietschnig, Marianne; Schmidt, Luca; Schurer, Andrew P.; Scott, E. Marian; Sexton, David; Sherwood, Steven C.; Vargas Zeppetello, Lucas R.; Zhang, Yi</b> (2024). Theory and the future of land-climate science. <i>Nature Geoscience 17(11)</i>: 1079-1086. <a href=\"https://dx.doi.org/10.1038/s41561-024-01553-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01553-8</a>","StandardTitle":"Theory and the future of land-climate science","AuthorsString":"Byrne, Michael P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":298399,"RR":"<b>Brunelli, D.; Cipriani, A.; Bonatti, E.</b> (2018). Thermal effects of pyroxenites on mantle melting below mid-ocean ridges. <i>Nature Geoscience 11(7)</i>: 520-525. <a href=\"https://dx.doi.org/10.1038/s41561-018-0139-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0139-z</a>","StandardTitle":"Thermal effects of pyroxenites on mantle melting below mid-ocean ridges","AuthorsString":"Brunelli, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":243949,"RR":"<b>Williams, G.; Maksym, T.; Wilkinson, J.; Kunz, C.; Murphy, C.; Kimball, P.; Singh, H.</b> (2015). Thick and deformed Antarctic sea ice mapped with autonomous underwater vehicles. <i>Nature Geoscience 8(1)</i>: 61-67. <a href=\"http://dx.doi.org/10.1038/ngeo2299\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2299</a>","StandardTitle":"Thick and deformed Antarctic sea ice mapped with autonomous underwater vehicles","AuthorsString":"Williams, G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":355456,"RR":"<b>Mackintosh, A.</b> (2022). Thwaites Glacier and the bed beneath. <i>Nature Geoscience 15</i>: 687–688. <a href=\"https://dx.doi.org/10.1038/s41561-022-01020-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01020-2</a>","StandardTitle":"Thwaites Glacier and the bed beneath","AuthorsString":"Mackintosh, A.","BibLvlCode":"AS"},{"BRefID":289158,"RR":"<b>Hoitink, A.J.F.; Wang, Z.B.; Vermeulen, B.; Huismans, Y.; Kästner, K.</b> (2017). Tidal controls on river delta morphology. <i>Nature Geoscience 10(9)</i>: 637-645. <a href=\"https://dx.doi.org/10.1038/ngeo3000\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3000</a>","StandardTitle":"Tidal controls on river delta morphology","AuthorsString":"Hoitink, A.J.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":245086,"RR":"<b>Rippeth, T.P.; Lincoln, B.J.; Len, Y.-D.; Green, J.A.M.; Sundfjord, A.; Bacon, S.</b> (2015). Tide-mediated warming of Arctic halocline by Atlantic heat fluxes over rough topography. <i>Nature Geoscience 8(3)</i>: 191–194. <a href=\"http://dx.doi.org/10.1038/ngeo2350\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2350</a>","StandardTitle":"Tide-mediated warming of Arctic halocline by Atlantic heat fluxes over rough topography","AuthorsString":"Rippeth, T.P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396173,"RR":"<b>Brett, H.; Tromp, J.; Deuss, A.</b> (2024). Tilted transverse isotropy in Earth’s inner core. <i>Nature Geoscience 17(10)</i>: 1059-1064. <a href=\"https://dx.doi.org/10.1038/s41561-024-01539-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01539-6</a>","StandardTitle":"Tilted transverse isotropy in Earth’s inner core","AuthorsString":"Brett, H.; Tromp, J.; Deuss, A.","BibLvlCode":"AS"},{"BRefID":393305,"RR":"<b>Bradley, A.T.; Hewitt, I.J.</b> (2024). Tipping point in ice-sheet grounding-zone melting due to ocean water intrusion. <i>Nature Geoscience 17(7)</i>: 631-637. <a href=\"https://dx.doi.org/10.1038/s41561-024-01465-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01465-7</a>","StandardTitle":"Tipping point in ice-sheet grounding-zone melting due to ocean water intrusion","AuthorsString":"Bradley, A.T.; Hewitt, I.J.","BibLvlCode":"AS"},{"BRefID":349746,"RR":"<b>Shillington, D.J.</b> (2022). Top-down control on water subduction. <i>Nature Geoscience 15(2)</i>: 94-95. <a href=\"https://dx.doi.org/10.1038/s41561-021-00883-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00883-1</a>","StandardTitle":"Top-down control on water subduction","AuthorsString":"Shillington, D.J.","BibLvlCode":"AS"},{"BRefID":435868,"RR":"<b>Ortiz-Guerrero, C.</b> (2025). Towards effective institutional hazard management. <i>Nature Geoscience 18(11)</i>: 1084-1087. <a href=\"https://dx.doi.org/10.1038/s41561-025-01827-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01827-9</a>","StandardTitle":"Towards effective institutional hazard management","AuthorsString":"Ortiz-Guerrero, C.","BibLvlCode":"AS"},{"BRefID":408009,"RR":"<b>Chen, X.; Ostrander, C.M.; Holdaway, B.J.; Kendall, B.; Anbar, A.D.; Nielsen, S.G.; Owens, J.D.</b> (2025). Transient marine bottom water oxygenation on continental shelves by 2.65 billion years ago. <i>Nature Geoscience 18(5)</i>: 423-429. <a href=\"https://dx.doi.org/10.1038/s41561-025-01681-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01681-9</a>","StandardTitle":"Transient marine bottom water oxygenation on continental shelves by 2.65 billion years ago","AuthorsString":"Chen, X. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":353957,"RR":"<b>Gernon, T.M.; Barr, R.; Fitton, J.G.; Hincks, T.K.; Keir, D.; Longman, J.; Merdith, A.S.; Mitchell, R.N.; Palmer, M.R.</b> (2022). Transient mobilization of subcrustal carbon coincident with Palaeocene–Eocene Thermal Maximum. <i>Nature Geoscience 15(7)</i>: 573-579. <a href=\"https://dx.doi.org/10.1038/s41561-022-00967-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00967-6</a>","StandardTitle":"Transient mobilization of subcrustal carbon coincident with Palaeocene–Eocene Thermal Maximum","AuthorsString":"Gernon, T.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":344778,"RR":"<b>Newby, S.M.; Owens, J.D.; Schoepfer, S.D.; Algeo, T.J.</b> (2021). Transient ocean oxygenation at end-Permian mass extinction onset shown by thallium isotopes. <i>Nature Geoscience 14(9)</i>: 678-683. <a href=\"https://dx.doi.org/10.1038/s41561-021-00802-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00802-4</a>","StandardTitle":"Transient ocean oxygenation at end-Permian mass extinction onset shown by thallium isotopes","AuthorsString":"Newby, S.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":321490,"RR":"<b>Azadi, M.; Northey, S.A.; Ali, S.H.; Edraki, M.</b> (2020). Transparency on greenhouse gas emissions from mining to enable climate change mitigation. <i>Nature Geoscience 13(2)</i>: 100-104. <a href=\"https://dx.doi.org/10.1038/s41561-020-0531-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0531-3</a>","StandardTitle":"Transparency on greenhouse gas emissions from mining to enable climate change mitigation","AuthorsString":"Azadi, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":302782,"RR":"(2018). Treasures from the deep. <i>Nature Geoscience 11(11)</i>: 801-801. <a href=\"https://dx.doi.org/10.1038/s41561-018-0260-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0260-z</a>","StandardTitle":"Treasures from the deep","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":350630,"RR":"<b>Swartz, J.M.; Cardenas, B.T.; Mohrig, D.; Passalacqua, P.</b> (2022). Tributary channel networks formed by depositional processes. <i>Nature Geoscience 15</i>: 216-221. <a href=\"https://dx.doi.org/10.1038/s41561-022-00900-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00900-x</a>","StandardTitle":"Tributary channel networks formed by depositional processes","AuthorsString":"Swartz, J.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":323338,"RR":"<b>England, M.R.; Polvani, L.M.; Sun, L.; Deser, C.</b> (2020). Tropical climate responses to projected Arctic and Antarctic sea-ice loss. <i>Nature Geoscience 13(4)</i>: 275-281. <a href=\"https://dx.doi.org/10.1038/s41561-020-0546-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0546-9</a>","StandardTitle":"Tropical climate responses to projected Arctic and Antarctic sea-ice loss","AuthorsString":"England, M.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291792,"RR":"<b>Newton, A.</b> (2018). Tropical interchange. <i>Nature Geoscience 11(1)</i>: 20. <a href=\"https://dx.doi.org/10.1038/s41561-017-0049-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0049-5</a>","StandardTitle":"Tropical interchange","AuthorsString":"Newton, A.","BibLvlCode":"AS"},{"BRefID":289758,"RR":"<b>Erhardt, A.</b> (2017). Tropical ties. <i>Nature Geoscience 10(10)</i>: 714-715. <a href=\"https://dx.doi.org/10.1038/ngeo3025\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3025</a>","StandardTitle":"Tropical ties","AuthorsString":"Erhardt, A.","BibLvlCode":"AS"},{"BRefID":349087,"RR":"<b>Cheung, K.F.; Lay, T.; Sun, L.; Yamazaki, Y.</b> (2022). Tsunami size variability with rupture depth. <i>Nature Geoscience 15(1)</i>: 33-36. <a href=\"https://dx.doi.org/10.1038/s41561-021-00869-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00869-z</a>","StandardTitle":"Tsunami size variability with rupture depth","AuthorsString":"Cheung, K.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":287584,"RR":"<b>Bécel, A.; Shillington, D.J.; Delescluse, M.; Nedimovic, M.R.; Abers, G.A.; Saffer, D.M.; Webb, S.C.; Keranen, K.M.; Roche, P.-H.; Li, J.; Kuehn, H.</b> (2017). Tsunamigenic structures in a creeping section of the Alaska subduction zone. <i>Nature Geoscience 10(8)</i>: 609-613. <a href=\"https://dx.doi.org/10.1038/ngeo2990\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2990</a>","StandardTitle":"Tsunamigenic structures in a creeping section of the Alaska subduction zone","AuthorsString":"Bécel, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":308733,"RR":"(2019). Tsunamis revisited. <i>Nature Geoscience 12(3)</i>: 149-149. <a href=\"https://dx.doi.org/10.1038/s41561-019-0328-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0328-4</a>","StandardTitle":"Tsunamis revisited","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":248288,"RR":"<b>Shaw, T.A.; Voigt, A.</b> (2015). Tug of war on summertime circulation between radiative forcing and sea surface warming. <i>Nature Geoscience 8(7)</i>: 560-566. <a href=\"http://dx.doi.org/10.1038/ngeo2449\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2449</a>","StandardTitle":"Tug of war on summertime circulation between radiative forcing and sea surface warming","AuthorsString":"Shaw, T.A.; Voigt, A.","BibLvlCode":"AS"},{"BRefID":353952,"RR":"<b>Cresswell-Clay, N.; Ummenhofer, C.C.; Thatcher, D.L.; Wanamaker, A.D.; Denniston, R.F.; Asmerom, Y.; Polyak, V.J.</b> (2022). Twentieth-century Azores High expansion unprecedented in the past 1,200 years. <i>Nature Geoscience 15(7)</i>: 548-553. <a href=\"https://dx.doi.org/10.1038/s41561-022-00971-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00971-w</a>","StandardTitle":"Twentieth-century Azores High expansion unprecedented in the past 1,200 years","AuthorsString":"Cresswell-Clay, N. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":351419,"RR":"<b>Henson, S.A.; Laufkötter, C.; Leung, S.; Giering, S.L.C.; Palevsky, H.I.; Cavan, E.L.</b> (2022). Uncertain response of ocean biological carbon export in a changing world. <i>Nature Geoscience 15(4)</i>: 248-254. <a href=\"https://dx.doi.org/10.1038/s41561-022-00927-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-00927-0</a>","StandardTitle":"Uncertain response of ocean biological carbon export in a changing world","AuthorsString":"Henson, S.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":240067,"RR":"<b>Owen, M.J.; Maslin, M.A.</b> (2014). Underappreciated Atlantic tsunami risk. <i>Nature Geoscience 7(8)</i>: 550. <a href=\"http://dx.doi.org/10.1038/ngeo2206\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2206</a>","StandardTitle":"Underappreciated Atlantic tsunami risk","AuthorsString":"Owen, M.J.; Maslin, M.A.","BibLvlCode":"AS"},{"BRefID":391802,"RR":"<b>Ackerman Grunfeld, D.; Gilbert, D.; Hou, J.; Jones, A.M.; Lee, M.J.; Kibbey, T.C.G.; O’Carroll, D.M.</b> (2024). Underestimated burden of per- and polyfluoroalkyl substances in global surface waters and groundwaters. <i>Nature Geoscience 17(4)</i>: 340-346. <a href=\"https://dx.doi.org/10.1038/s41561-024-01402-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01402-8</a>","StandardTitle":"Underestimated burden of per- and polyfluoroalkyl substances in global surface waters and groundwaters","AuthorsString":"Ackerman Grunfeld, D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":249477,"RR":"<b>Peakall, J.</b> (2015). Undersea river patterns. <i>Nature Geoscience 8(9)</i>: 663–664. <a href=\"http://dx.doi.org/10.1038/ngeo2509\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2509</a>","StandardTitle":"Undersea river patterns","AuthorsString":"Peakall, J.","BibLvlCode":"AS"},{"BRefID":364405,"RR":"(2023). Underwater terraced deposits chronicle volcanic eruptions. <i>Nature Geoscience 16(5)</i>: 397-398. <a href=\"https://dx.doi.org/10.1038/s41561-023-01168-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01168-5</a>","StandardTitle":"Underwater terraced deposits chronicle volcanic eruptions","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":290678,"RR":"<b>Lacour, L.; Ardyna, M.; Stec, K.F.; Claustre, H.; Prieur, L.; Poteau, A.; Ribera d’Alcalà, M.; Iudicone, D.</b> (2017). Unexpected winter phytoplankton blooms in the North Atlantic subpolar gyre. <i>Nature Geoscience 10(11)</i>: 836-839. <a href=\"https://dx.doi.org/10.1038/ngeo3035\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3035</a>","StandardTitle":"Unexpected winter phytoplankton blooms in the North Atlantic subpolar gyre","AuthorsString":"Lacour, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":394035,"RR":"<b>Lecomte, N.</b> (2024). Unmasking Antarctica’s biodiversity. <i>Nature Geoscience 17(8)</i>: 714-715. <a href=\"https://dx.doi.org/10.1038/s41561-024-01502-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01502-5</a>","StandardTitle":"Unmasking Antarctica’s biodiversity","AuthorsString":"Lecomte, N.","BibLvlCode":"AS"},{"BRefID":361135,"RR":"(2023). Unravelling ENSO complexity. <i>Nature Geoscience 16(2)</i>: 105. <a href=\"https://dx.doi.org/10.1038/s41561-023-01134-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01134-1</a>","StandardTitle":"Unravelling ENSO complexity","AuthorsString":null,"BibLvlCode":"AS"},{"BRefID":337160,"RR":"<b>Melnick, D.</b> (2021). Unrushed megathrusts. <i>Nature Geoscience 14(5)</i>: 260-261. <a href=\"https://hdl.handle.net/10.1038/s41561-021-00750-z\" target=\"_blank\">https://hdl.handle.net/10.1038/s41561-021-00750-z</a>","StandardTitle":"Unrushed megathrusts","AuthorsString":"Melnick, D.","BibLvlCode":"AS"},{"BRefID":241876,"RR":"<b>Jung, G.</b> (2014). Uplift of Africa as a potential cause for Neogene intensification of the Benguela upwelling system. <i>Nature Geoscience 7(10)</i>: 741-747. <a href=\"http://dx.doi.org/10.1038/ngeo2249\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2249</a>","StandardTitle":"Uplift of Africa as a potential cause for Neogene intensification of the Benguela upwelling system","AuthorsString":"Jung, G.","BibLvlCode":"AS"},{"BRefID":349755,"RR":"<b>Arnulf, A.F.; Bassett, D.; Harding, A.J.; Kodaira, S.; Nakanishi, A.; Moore, G.</b> (2022). Upper-plate controls on subduction zone geometry, hydration and earthquake behaviour. <i>Nature Geoscience 15(2)</i>: 143-148. <a href=\"https://dx.doi.org/10.1038/s41561-021-00879-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00879-x</a>","StandardTitle":"Upper-plate controls on subduction zone geometry, hydration and earthquake behaviour","AuthorsString":"Arnulf, A.F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":396171,"RR":"<b>Sanfilippo, A.; Stracke, A.; Genske, F.; Scarani, S.; Cuffaro, M.; Basch, V.; Borghini, B.; Brunelli, D.; Ferrando, C.; Peyve, A.A.; Ligi, M.</b> (2024). Upwelling of melt-depleted mantle under Iceland. <i>Nature Geoscience 17(10)</i>: 1046-1052. <a href=\"https://dx.doi.org/10.1038/s41561-024-01532-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01532-z</a>","StandardTitle":"Upwelling of melt-depleted mantle under Iceland","AuthorsString":"Sanfilippo, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":259362,"RR":"<b>Haine, T.W.N.</b> (2016). Vagaries of Atlantic overturning. <i>Nature Geoscience 9(7)</i>: 479-480. <a href=\"http://dx.doi.org/10.1038/ngeo2748\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2748</a>","StandardTitle":"Vagaries of Atlantic overturning","AuthorsString":"Haine, T.W.N.","BibLvlCode":"AS"},{"BRefID":290677,"RR":"<b>Evans, C.D.; Futter, M.N.; Moldan, F.; Valinia, S.; Frogbrook, Z.; Kothawala, D.N.</b> (2017). Variability in organic carbon reactivity across lake residence time and trophic gradients. <i>Nature Geoscience 10(11)</i>: 832-835. <a href=\"https://dx.doi.org/10.1038/ngeo3051\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3051</a>","StandardTitle":"Variability in organic carbon reactivity across lake residence time and trophic gradients","AuthorsString":"Evans, C.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":241502,"RR":"<b>Müller, J.; Massé, G.; Stein, R.; Belt, S.T.</b> (2009). Variability of sea-ice conditions in the Fram Strait over the past 30,000 years. <i>Nature Geoscience 2(11)</i>: 772-776. <a href=\"http://dx.doi.org/10.1038/ngeo665\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo665</a>","StandardTitle":"Variability of sea-ice conditions in the Fram Strait over the past 30,000 years","AuthorsString":"Müller, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":319472,"RR":"<b>Moy, A.D.; Palmer, M.R.; Howard, W.R.; Bijma, J.; Cooper, M.J.; Calvo, E.; Pelejero, C.; Gagan, M.K.; Chalk, T.B.</b> (2019). Varied contribution of the Southern Ocean to deglacial atmospheric CO<sub>2</sub> rise. <i>Nature Geoscience 12(12)</i>: 1006-1011. <a href=\"https://dx.doi.org/10.1038/s41561-019-0473-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0473-9</a>","StandardTitle":"Varied contribution of the Southern Ocean to deglacial atmospheric CO<sub>2</sub> rise","AuthorsString":"Moy, A.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":437132,"RR":"<b>Wehrlé, A.; Lüthi, M.P.; Kneib-Walter, A.; Nap, A.; Rousseau, H.; Jouvet, G.; Walter, F.</b> (2026). Velocity and calving response of a major Greenland ice stream to a lake drainage event. <i>Nature Geoscience 19(1)</i>: 84-89. <a href=\"https://dx.doi.org/10.1038/s41561-025-01858-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01858-2</a>","StandardTitle":"Velocity and calving response of a major Greenland ice stream to a lake drainage event","AuthorsString":"Wehrlé, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":347565,"RR":"<b>Pohl, A.; Lu, Z.; Lu, W.; Stockey, R.G.; Elrick, M.; Li, M.; Desrochers, A.; Shen, Y.; He, R.; Finnegan, S.; Ridgwell, A.</b> (2021). Vertical decoupling in Late Ordovician anoxia due to reorganization of ocean circulation. <i>Nature Geoscience 14(11)</i>: 868-873. <a href=\"https://dx.doi.org/10.1038/s41561-021-00843-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00843-9</a>","StandardTitle":"Vertical decoupling in Late Ordovician anoxia due to reorganization of ocean circulation","AuthorsString":"Pohl, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":248287,"RR":"<b>Wesson, R.L.; Melnick, D.; Cisternas, M.; Ely, L.L.</b> (2015). Vertical deformation through a complete seismic cycle at Isla Santa María, Chile. <i>Nature Geoscience 8(7)</i>: 547-551. <a href=\"http://dx.doi.org/10.1038/ngeo2468\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2468</a>","StandardTitle":"Vertical deformation through a complete seismic cycle at Isla Santa María, Chile","AuthorsString":"Wesson, R.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":408003,"RR":"<b>Hunt, A.</b> (2025). Volcanic forcing of early oxygen. <i>Nature Geoscience 18(5)</i>: 376-376. <a href=\"https://dx.doi.org/10.1038/s41561-025-01706-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01706-3</a>","StandardTitle":"Volcanic forcing of early oxygen","AuthorsString":"Hunt, A.","BibLvlCode":"AS"},{"BRefID":284566,"RR":"<b>Kelley, D.</b> (2017). Vulcan rule beneath the sea. <i>Nature Geoscience 10(4)</i>: 251-253. <a href=\"https://dx.doi.org/10.1038/ngeo2929\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2929</a>","StandardTitle":"Vulcan rule beneath the sea","AuthorsString":"Kelley, D.","BibLvlCode":"AS"},{"BRefID":395754,"RR":"<b>Toda, M.; Kosaka, Y.; Miyamoto, A.; Watanabe, M.</b> (2024). Walker circulation strengthening driven by sea surface temperature changes outside the tropics. <i>Nature Geoscience 17(9)</i>: 858-865. <a href=\"https://dx.doi.org/10.1038/s41561-024-01510-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01510-5</a>","StandardTitle":"Walker circulation strengthening driven by sea surface temperature changes outside the tropics","AuthorsString":"Toda, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":283780,"RR":"<b>Samartin, S.; Heiri, O.; Joos, F.; Renssen, H.; Franke, J.; Brönnimann, S.; Tinner, W.</b> (2017). Warm Mediterranean mid-Holocene summers inferred from fossil midge assemblages. <i>Nature Geoscience 10(3)</i>: 207-212. <a href=\"http://dx.doi.org/10.1038/ngeo2891\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2891</a>","StandardTitle":"Warm Mediterranean mid-Holocene summers inferred from fossil midge assemblages","AuthorsString":"Samartin, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":287574,"RR":"<b>Bastos, A.</b> (2017). Warmer Arctic weakens vegetation. <i>Nature Geoscience 10(8)</i>: 543-544. <a href=\"https://dx.doi.org/10.1038/ngeo2989\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2989</a>","StandardTitle":"Warmer Arctic weakens vegetation","AuthorsString":"Bastos, A.","BibLvlCode":"AS"},{"BRefID":414062,"RR":"<b>Lu, W.; Oppo, D.W.; Liu, Z.; Zhu, C.; Condron, A.; Lynch-Stieglitz, J.; Guo, W.; Hess, A.V.; Wang, S.</b> (2025). Warmer shallow Atlantic during deglaciation and early Holocene due to weaker overturning circulation. <i>Nature Geoscience 18(8)</i>: 787-792. <a href=\"https://dx.doi.org/10.1038/s41561-025-01751-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01751-y</a>","StandardTitle":"Warmer shallow Atlantic during deglaciation and early Holocene due to weaker overturning circulation","AuthorsString":"Lu, W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":302784,"RR":"<b>Bindoff, N.L.</b> (2018). Warming and freshening trends. <i>Nature Geoscience 11(11)</i>: 803-804. <a href=\"https://dx.doi.org/10.1038/s41561-018-0239-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0239-9</a>","StandardTitle":"Warming and freshening trends","AuthorsString":"Bindoff, N.L.","BibLvlCode":"AS"},{"BRefID":367827,"RR":"<b>Lauber, J.; Hattermann, T.; de Steur, L.; Darelius, E.; Auger, M.; Nøst, O.A.; Moholdt, G.</b> (2023). Warming beneath an East Antarctic ice shelf due to increased subpolar westerlies and reduced sea ice. <i>Nature Geoscience 16(10)</i>: 877-885. <a href=\"https://dx.doi.org/10.1038/s41561-023-01273-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01273-5</a>","StandardTitle":"Warming beneath an East Antarctic ice shelf due to increased subpolar westerlies and reduced sea ice","AuthorsString":"Lauber, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":246328,"RR":"<b>Steinle, L.; Graves, C.A.; Treude, T.; Ferré, B.; Biastoch, A.; Bussmann, I.; Berndt, C.; Krastel, S.; James, R.H.; Behrens, E.; Böning, C.W.; Greinert, J.; Sapart, C.-J.; Scheinert, M.; Sommer, S.; Lehmann, M.F.; Niemann, H.</b> (2015). Water column methanotrophy controlled by a rapid oceanographic switch. <i>Nature Geoscience 8(5)</i>: 378-382. <a href=\"http://dx.doi.org/10.1038/NGEO2420\" target=\"_blank\">dx.doi.org/10.1038/NGEO2420</a>","StandardTitle":"Water column methanotrophy controlled by a rapid oceanographic switch","AuthorsString":"Steinle, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":439207,"RR":"<b>Casado, M.; Bailey, A.; Leroy-Dos Santos, C.; Fourré, E.; Favier, V.; Agosta, C.; Dutrievoz, N.; Kittel, C.; Arnaud, L.; Prié, F.; Akers, P.D.; Cauquoin, A.; Werner, M.; Janssen, L.; Stenni, B.; Dreossi, G.; Spolaor, A.; Petteni, A.; Savarino, J.; Landais, A.</b> (2026). Water isotope–temperature relationship variability across Antarctica set by atmospheric circulation. <i>Nature Geoscience 19(5)</i>: 581-588. <a href=\"https://dx.doi.org/10.1038/s41561-026-01961-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01961-y</a>","StandardTitle":"Water isotope–temperature relationship variability across Antarctica set by atmospheric circulation","AuthorsString":"Casado, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":260851,"RR":"<b>Abernathey, R.P.; Cerovecki, I.; Holland, P.R.; Newsom, E.R.; Mazloff, M.; Talley, L.D.</b> (2016). Water-mass transformation by sea ice in the upper branch of the Southern Ocean overturning. <i>Nature Geoscience 9(8)</i>: 596-601. <a href=\"http://dx.doi.org/10.1038/ngeo2749\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2749</a>","StandardTitle":"Water-mass transformation by sea ice in the upper branch of the Southern Ocean overturning","AuthorsString":"Abernathey, R.P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291797,"RR":"<b>Mehouachi, F.; Singh, S.C.</b> (2018). Water-rich sublithospheric melt channel in the equatorial Atlantic Ocean. <i>Nature Geoscience 11(1)</i>: 65-69. <a href=\"https://dx.doi.org/10.1038/s41561-017-0034-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0034-z</a>","StandardTitle":"Water-rich sublithospheric melt channel in the equatorial Atlantic Ocean","AuthorsString":"Mehouachi, F.; Singh, S.C.","BibLvlCode":"AS"},{"BRefID":241877,"RR":"<b>Möller, I.; Kudella, M.; Rupprecht, F.; Spencer, T.; Paul, M.; van Wesenbeeck, B.K.; Wolters, G.; Jensen, K.; Bouma, T.J.; Miranda-Lange, M.; Schimmels, S.</b> (2014). Wave attenuation over coastal salt marshes under storm surge conditions. <i>Nature Geoscience 7(10)</i>: 727-731. <a href=\"https://dx.doi.org/10.1038/ngeo2251\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo2251</a>","StandardTitle":"Wave attenuation over coastal salt marshes under storm surge conditions","AuthorsString":"Möller, I. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":406637,"RR":"<b>Fan, W.; Wang, T.; Barbot, S.; Fang, D.; Ran, J.; Luo, H.</b> (2025). Weak asthenosphere beneath the Eurasian interior inferred from Aral Sea desiccation. <i>Nature Geoscience 18(4)</i>: 351-357. <a href=\"https://dx.doi.org/10.1038/s41561-025-01664-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01664-w</a>","StandardTitle":"Weak asthenosphere beneath the Eurasian interior inferred from Aral Sea desiccation","AuthorsString":"Fan, W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":325388,"RR":"<b>Dumberry, M.; More, C.</b> (2020). Weak magnetic field changes over the Pacific due to high conductance in lowermost mantle. <i>Nature Geoscience 13(7)</i>: 516-520. <a href=\"https://dx.doi.org/10.1038/s41561-020-0589-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0589-y</a>","StandardTitle":"Weak magnetic field changes over the Pacific due to high conductance in lowermost mantle","AuthorsString":"Dumberry, M.; More, C.","BibLvlCode":"AS"},{"BRefID":437757,"RR":"<b>Guan, S.; Huang, M.; Cai, W.; Zhang, Z.; Lin, I.-I; Kim, H.-S.; Zhou, L.; Lin, X.; Xu, Z.; Jin, F.-F.; Mei, W.; Wang, Q.; Zhou, C.; Meng, Z.; Tian, J.; Zhao, W.</b> (2026). Weak self-induced cooling of tropical cyclones amid fast sea surface warming. <i>Nature Geoscience 19(2)</i>: 153-158. <a href=\"https://dx.doi.org/10.1038/s41561-025-01879-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01879-x</a>","StandardTitle":"Weak self-induced cooling of tropical cyclones amid fast sea surface warming","AuthorsString":"Guan, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392281,"RR":"<b>Biló, T.C.; Perez, R.C.; Dong, S.; Johns, W.; Kanzow, T.</b> (2024). Weakening of the Atlantic Meridional Overturning Circulation abyssal limb in the North Atlantic. <i>Nature Geoscience 17(5)</i>: 419-425. <a href=\"https://dx.doi.org/10.1038/s41561-024-01422-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01422-4</a>","StandardTitle":"Weakening of the Atlantic Meridional Overturning Circulation abyssal limb in the North Atlantic","AuthorsString":"Biló, T.C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":404840,"RR":"<b>Pontes, G.M.; Menviel, L.</b> (2024). Weakening of the Atlantic Meridional Overturning Circulation driven by subarctic freshening since the mid-twentieth century. <i>Nature Geoscience 17(12)</i>: 1291-1298. <a href=\"https://dx.doi.org/10.1038/s41561-024-01568-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01568-1</a>","StandardTitle":"Weakening of the Atlantic Meridional Overturning Circulation driven by subarctic freshening since the mid-twentieth century","AuthorsString":"Pontes, G.M.; Menviel, L.","BibLvlCode":"AS"},{"BRefID":404839,"RR":"<b>Akabane, T.K.; Chiessi, C.M.; Hirota, M.; Bouimetarhan, I.; Prange, M.; Mulitza, S.; Bertassoli Jr, D.J.; Häggi, C.; Staal, A.; Lohmann, G.; Boers, N.; Daniau, A.-L.; Oliveira, R.S.; Campos, M.C.; Shi, X.; De Oliveira, P.E.</b> (2024). Weaker Atlantic overturning circulation increases the vulnerability of northern Amazon forests. <i>Nature Geoscience 17(12)</i>: 1284-1290. <a href=\"https://dx.doi.org/10.1038/s41561-024-01578-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01578-z</a>","StandardTitle":"Weaker Atlantic overturning circulation increases the vulnerability of northern Amazon forests","AuthorsString":"Akabane, T.K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":316664,"RR":"<b>Holland, P.R.; Bracegirdle, T.J.; Dutrieux, P.; Jenkins, A.; Steig, E.J.</b> (2019). West Antarctic ice loss influenced by internal climate variability and anthropogenic forcing. <i>Nature Geoscience 12(9)</i>: 718–724. <a href=\"https://dx.doi.org/10.1038/s41561-019-0420-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0420-9</a>","StandardTitle":"West Antarctic ice loss influenced by internal climate variability and anthropogenic forcing","AuthorsString":"Holland, P.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":301862,"RR":"<b>Jenkins, A.; Shoosmith, D.; Dutrieux, P.; Jacobs, S.; Kim, T.W.; Lee, S.H.; Ha, H.K.; Stammerjohn, S.</b> (2018). West Antarctic Ice Sheet retreat in the Amundsen Sea driven by decadal oceanic variability. <i>Nature Geoscience 11(10)</i>: 733-738. <a href=\"https://dx.doi.org/10.1038/s41561-018-0207-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0207-4</a>","StandardTitle":"West Antarctic Ice Sheet retreat in the Amundsen Sea driven by decadal oceanic variability","AuthorsString":"Jenkins, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":360455,"RR":"<b>Ohneiser, C.; Hulbe, C.L.; Beltran, C.; Riesselman, C.R.; Moy, C.M.; Condon, D.B.; Worthington, R.A.</b> (2023). West Antarctic ice volume variability paced by obliquity until 400,000 years ago. <i>Nature Geoscience 16(1)</i>: 44-49. <a href=\"https://dx.doi.org/10.1038/s41561-022-01088-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-022-01088-w</a>","StandardTitle":"West Antarctic ice volume variability paced by obliquity until 400,000 years ago","AuthorsString":"Ohneiser, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":318161,"RR":"<b>Wille, J.D.; Favier, V.; Dufour, A.; Gorodetskaya, I.V.; Turner, J.; Agosta, C.; Codron, F.</b> (2019). West Antarctic surface melt triggered by atmospheric rivers. <i>Nature Geoscience 12(11)</i>: 911-916. <a href=\"https://dx.doi.org/10.1038/s41561-019-0460-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0460-1</a>","StandardTitle":"West Antarctic surface melt triggered by atmospheric rivers","AuthorsString":"Wille, J.D. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":436574,"RR":"<b>Thomas, Z.A.; Cadd, H.; Turney, C.; Becerra-Valdivia, L.; Haines, H.A.; Marjo, C.; Fogwill, C.; Carter, S.; Brickle, P.</b> (2025). Westerly wind shifts drove Southern Hemisphere mid-latitude peat growth since the last glacial. <i>Nature Geoscience 18(12)</i>: 1245-1251. <a href=\"https://dx.doi.org/10.1038/s41561-025-01842-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01842-w</a>","StandardTitle":"Westerly wind shifts drove Southern Hemisphere mid-latitude peat growth since the last glacial","AuthorsString":"Thomas, Z.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":435871,"RR":"<b>Bucciarelli, E.; Penven, P.; Pous, S.; Tagliabue, A.</b> (2025). Western Indian subantarctic phytoplankton blooms fertilized by iron-enriched Agulhas water. <i>Nature Geoscience 18(11)</i>: 1152-1158. <a href=\"https://dx.doi.org/10.1038/s41561-025-01823-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01823-z</a>","StandardTitle":"Western Indian subantarctic phytoplankton blooms fertilized by iron-enriched Agulhas water","AuthorsString":"Bucciarelli, E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":291798,"RR":"<b>Zhou, Q.; Liu, L.; Hu, J.</b> (2018). Western US volcanism due to intruding oceanic mantle driven by ancient Farallon slabs. <i>Nature Geoscience 11(1)</i>: 70-76. <a href=\"https://dx.doi.org/10.1038/s41561-017-0035-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-017-0035-y</a>","StandardTitle":"Western US volcanism due to intruding oceanic mantle driven by ancient Farallon slabs","AuthorsString":"Zhou, Q. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":320517,"RR":"<b>Rugenstein, J.K.C.</b> (2020). What goes down must come up. <i>Nature Geoscience 13(1)</i>: 5-7. <a href=\"https://dx.doi.org/10.1038/s41561-019-0514-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-019-0514-4</a>","StandardTitle":"What goes down must come up","AuthorsString":"Rugenstein, J.K.C.","BibLvlCode":"AS"},{"BRefID":289759,"RR":"<b>Olive, J.-A.</b> (2017). When less water means more fire. <i>Nature Geoscience 10(10)</i>: 718-719. <a href=\"https://dx.doi.org/10.1038/ngeo3040\" target=\"_blank\">https://dx.doi.org/10.1038/ngeo3040</a>","StandardTitle":"When less water means more fire","AuthorsString":"Olive, J.-A.","BibLvlCode":"AS"},{"BRefID":306499,"RR":"<b>Friess, D.A.</b> (2019). Where the tallest mangroves are. <i>Nature Geoscience 12(1)</i>: 4-5. <a href=\"https://dx.doi.org/10.1038/s41561-018-0280-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0280-8</a>","StandardTitle":"Where the tallest mangroves are","AuthorsString":"Friess, D.A.","BibLvlCode":"AS"},{"BRefID":324985,"RR":"<b>Schill, G.P.; Froyd, K.D.; Bian, H.; Kupc, A.; Williamson, C.; Brock, C.A.; Ray, E.; Hornbrook, R.S.; Hills, A.J.; Apel, E.C.; Chin, M.; Colarco, P.R.; Murphy, D.M.</b> (2020). Widespread biomass burning smoke throughout the remote troposphere. <i>Nature Geoscience 13(6)</i>: 422-427. <a href=\"https://dx.doi.org/10.1038/s41561-020-0586-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-020-0586-1</a>","StandardTitle":"Widespread biomass burning smoke throughout the remote troposphere","AuthorsString":"Schill, G.P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":367823,"RR":"<b>Singh, N.K.; Van Meter, K.J.; Basu, N.B.</b> (2023). Widespread increases in soluble phosphorus concentrations in streams across the transboundary Great Lakes Basin. <i>Nature Geoscience 16(10)</i>: 893-900. <a href=\"https://dx.doi.org/10.1038/s41561-023-01257-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01257-5</a>","StandardTitle":"Widespread increases in soluble phosphorus concentrations in streams across the transboundary Great Lakes Basin","AuthorsString":"Singh, N.K.; Van Meter, K.J.; Basu, N.B.","BibLvlCode":"AS"},{"BRefID":395755,"RR":"<b>Poizat, M.; Picard, G.; Arnaud, L.; Narteau, C.; Amory, C.; Brun, F.</b> (2024). Widespread longitudinal snow dunes in Antarctica shaped by sintering. <i>Nature Geoscience 17(9)</i>: 889-895. <a href=\"https://dx.doi.org/10.1038/s41561-024-01506-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01506-1</a>","StandardTitle":"Widespread longitudinal snow dunes in Antarctica shaped by sintering","AuthorsString":"Poizat, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":240977,"RR":"<b>Skarke, A.; Ruppel, C.; Kodis, M.; Brothers, D.; Lobecker, E.</b> (2014). Widespread methane leakage from the sea floor on the northern US Atlantic margin. <i>Nature Geoscience 7(9)</i>: 657–661. <a href=\"http://dx.doi.org/10.1038/ngeo2232\" target=\"_blank\">http://dx.doi.org/10.1038/ngeo2232</a>","StandardTitle":"Widespread methane leakage from the sea floor on the northern US Atlantic margin","AuthorsString":"Skarke, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":438824,"RR":"<b>Kalinski, Jarmo-Charles J.; Pakkir Mohamed Shah, Abzer K.; Ruiz Brandão da Costa, Bruno; Farrell, Shane P.; Schellenberg, Lisa; Graves, Lana G.; Schramm, Tilman; Stincone, Paolo; Koester, Irina; Stephens, Brandon M.; Torres, Ralph R.; Cancelada, Lucia; Utermann-Thüsing, Caroline; Quinlan, Zachary A.; Wegley Kelly, Linda; Carlson, Craig A.; Castillo-Ilabaca, Cristóbal; Pantoja-Gutiérrez, Silvio; Beman, J. Michael; Hartmann, Aaron; Aron, Allegra; Siwe Noundou, Xavier; Dorrington, Rosemary A.; Tasdemir, Deniz; Haas, Andreas F.; Dorrestein, Pieter C.; Nelson, Craig E.; Aluwihare, Lihini I.; Wang, Mingxun; Petras, Daniel</b> (2026). Widespread presence of anthropogenic compounds in marine dissolved organic matter. <i>Nature Geoscience 19(4)</i>: 478-487. <a href=\"https://dx.doi.org/10.1038/s41561-026-01928-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-026-01928-z</a>","StandardTitle":"Widespread presence of anthropogenic compounds in marine dissolved organic matter","AuthorsString":"Kalinski, Jarmo-Charles J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":363313,"RR":"<b>Wallis, B.J.; Hogg, A.E.; Van Wessem, J.M.; Davison, B.J.; van den Broeke, M.R.</b> (2023). Widespread seasonal speed-up of west Antarctic Peninsula glaciers from 2014 to 2021. <i>Nature Geoscience 16(3)</i>: 231-237. <a href=\"https://dx.doi.org/10.1038/s41561-023-01131-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-023-01131-4</a>","StandardTitle":"Widespread seasonal speed-up of west Antarctic Peninsula glaciers from 2014 to 2021","AuthorsString":"Wallis, B.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":306504,"RR":"<b>Steinberger, B.; Bredow, E.; Lebedev, S.; Schaeffer, A.; Torsvik, T.H.</b> (2019). Widespread volcanism in the Greenland–North Atlantic region explained by the Iceland plume. <i>Nature Geoscience 12(1)</i>: 61-68. <a href=\"https://dx.doi.org/10.1038/s41561-018-0251-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0251-0</a>","StandardTitle":"Widespread volcanism in the Greenland–North Atlantic region explained by the Iceland plume","AuthorsString":"Steinberger, B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":391808,"RR":"<b>Liu, Z.; Gu, S.; Zou, S.; Zhang, S.; Yu, Y.; He, C.</b> (2024). Wind-steered Eastern Pathway of the Atlantic Meridional Overturning Circulation. <i>Nature Geoscience 17(4)</i>: 353-360. <a href=\"https://dx.doi.org/10.1038/s41561-024-01407-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-024-01407-3</a>","StandardTitle":"Wind-steered Eastern Pathway of the Atlantic Meridional Overturning Circulation","AuthorsString":"Liu, Z. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":345727,"RR":"<b>Stone, D.A.</b> (2021). Winter isn’t what it used to be. <i>Nature Geoscience 14(10)</i>: 712-713. <a href=\"https://dx.doi.org/10.1038/s41561-021-00832-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00832-y</a>","StandardTitle":"Winter isn’t what it used to be","AuthorsString":"Stone, D.A.","BibLvlCode":"AS"},{"BRefID":406041,"RR":"<b>Hansen, K.; Karlsson, N.B.; How, P.; Poulsen, E.; Mortensen, J.; Rysgaard, S.</b> (2025). Winter subglacial meltwater detected in a Greenland fjord. <i>Nature Geoscience 18(3)</i>: 219-225. <a href=\"https://dx.doi.org/10.1038/s41561-025-01652-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01652-0</a>","StandardTitle":"Winter subglacial meltwater detected in a Greenland fjord","AuthorsString":"Hansen, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":303662,"RR":"<b>Pavelsky, T.M.</b> (2018). World’s landlocked basins drying. <i>Nature Geoscience 11(12)</i>: 892-893. <a href=\"https://dx.doi.org/10.1038/s41561-018-0269-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-018-0269-3</a>","StandardTitle":"World’s landlocked basins drying","AuthorsString":"Pavelsky, T.M.","BibLvlCode":"AS"},{"BRefID":345732,"RR":"<b>Goyal, R.; Jucker, M.; Sen Gupta, A.; Hendon, H.H.; England, M.H.</b> (2021). Zonal wave 3 pattern in the Southern Hemisphere generated by tropical convection. <i>Nature Geoscience 14(10)</i>: 732-738. <a href=\"https://dx.doi.org/10.1038/s41561-021-00811-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-021-00811-3</a>","StandardTitle":"Zonal wave 3 pattern in the Southern Hemisphere generated by tropical convection","AuthorsString":"Goyal, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":437764,"RR":"<b>Wu, S.; Mazaud, A.; Michel, E.; Erb, M.P.; Stocker, T.F.; Amsler, H.E.; Le Tallec-Carado, P.; Lamy, F.; Jaccard, S.L.</b> (2026). Zonally asymmetric changes in the Antarctic Circumpolar Current strength over the past million years. <i>Nature Geoscience 19(2)</i>: 201-208. <a href=\"https://dx.doi.org/10.1038/s41561-025-01901-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41561-025-01901-2</a>","StandardTitle":"Zonally asymmetric changes in the Antarctic Circumpolar Current strength over the past million years","AuthorsString":"Wu, S. <i>et al.</i>","BibLvlCode":"AS"}],"BEntOpen":118012,"BEntPrivate":null,"availability":[{"BInstID":229819,"LibID":36,"BRefID":123796,"EmbargoDate":null,"FullEmbargoDate":null,"PhysMedID":16,"hasOCRd":null,"ShelfLocCode":null,"RFID":null,"PaidValue":null,"Medium":"Server","Description":null,"Acronym":"VLIZ","Library":"Vlaams Instituut voor de Zee","DutchTerm":"Digitaal Archief","URL":null,"ClassifID":257,"Classification":"Digital Archive","ReqLink":null,"ClassifTypID":null,"URLLocation":"https://www.vliz.be/imisdocs/publications/","SubDir":0,"InternalReq":null,"LoggedInReq":null,"Disclaimer":null,"DutchDisclaimer":null,"FileFormat":null,"FileDescr":null,"InsPub":1,"InsID":36,"FileFormID":null,"LendableFlag":1,"PublicFlag":1,"orderLib":"A","Notes":null,"AccConID":null,"AccessConstraint":null,"LicURL":null}],"litstyles":null,"thespers":null,"arch2discl":805,"SERpubls":null,"MONpubls":null,"pictures":[],"thestermsPath":null,"thestermsASFA":null,"taxtermsASFA":null,"geotermsASFA":null,"collections":null,"conf":null,"proj":null,"Physdatasets":null,"spcols":{"805":{"SpName":"Koninklijk Nederlands Instituut voor Onderzoek der Zee","SpColID":805,"ParSpColID":null,"TopParID":null,"ShortName":"NIOZ","URLLocation":"https://www.vliz.be/imis/nioz/imis.php?refid=","LibID":2779,"OpenRepoFlag":1,"SpTypID":1,"TopParIDNotWebsite":null,"SpColPath":"NIOZ"}},"doi":null,"publs":[{"PublID":2828,"PublName":"Nature Publishing Group","InsID":null,"PersID":null,"INBOID":7394,"OrderNr":1}],"serparttypes":["A"],"monauthors":null,"MParts":null,"SParts":null,"hLibs":[{"LibID":36,"Library":"Vlaams Instituut voor de Zee","InsID":36,"PublicFlag":1,"holdings":[{"HoldingOrder":1,"FromYear":"2008","FromVol":"1","FromNr":null,"ToYear":"current issue","ToVol":null,"ToNr":null,"Medium":"Server","DutchTerm":"Server","BInstID":229819}]}],"langs":[{"BEntID":118012,"AbstractFlag":0,"LangID":15,"LangCode":"en","Lang":"English","DutchTerm":"Engels","LangCodeExtended":"eng"}],"urls":[{"URL":"www.nature.com/ngeo/index.html","externalID":null,"URLTypeCode":null,"URLID":23179,"URLTypID":null,"URLType":null,"URLPrefix":null}],"thesterms":null,"taxterms":null,"geoterms":null,"othterms":null,"asfacodes":null,"asfa2codes":null,"thestermsFRIS":null,"taxtermsFRIS":null,"geotermsFRIS":null,"othtermsFRIS":null,"resmessage":"","complete":1,"sessions":{"newSesName":"Chisala, Chilekwa, C.","newSesDate":{"date":"2008-07-14 09:29:08.203000","timezone_type":3,"timezone":"Europe/Brussels"},"updSesName":"Haspeslagh, Jan, J.","updSesDate":{"date":"2015-08-11 08:48:02.167000","timezone_type":3,"timezone":"Europe/Brussels"}}}