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Arctic amplification modulated by Atlantic Multidecadal Oscillation and greenhouse forcing on multidecadal to century scales. <i>Nature Comm. 13</i>: 1865. <a href=\"https://dx.doi.org/10.1038/s41467-022-29523-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-022-29523-x</a>","StandardTitle":"Arctic amplification modulated by Atlantic Multidecadal Oscillation and greenhouse forcing on multidecadal to century scales","AuthorsString":"Fang, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":285590,"RR":"<b>Tedesco, M.; Mote, T.; Fettweis, X.; Hanna, E.; Jeyaratnam, J.; Booth, J.F.; Datta, R.; Briggs, K.</b> (2016). 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Arctic sea ice is an important temporal sink and means of transport for microplastic. <i>Nature Comm. 9(1)</i>: 12 pp. <a href=\"https://dx.doi.org/10.1038/s41467-018-03825-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-018-03825-5</a>","StandardTitle":"Arctic sea ice is an important temporal sink and means of transport for microplastic","AuthorsString":"Peeken, I. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":435598,"RR":"<b>Zhao, P.; Li, Y.; Zhang, C.; Kang, T.; He, Z.; Huang, G.; Zhang, S.; Zhang, X.; Xu, Y.; Kong, W.</b> (2025). Arctic Sea route access reshapes global shipping carbon emissions. <i>Nature Comm. 16(1)</i>: 8431. <a href=\"https://dx.doi.org/10.1038/s41467-025-64437-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-025-64437-4</a>","StandardTitle":"Arctic Sea route access reshapes global shipping carbon emissions","AuthorsString":"Zhao, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":313800,"RR":"<b>Matsumura, S.; Yu, K.</b> (2019). Arctic–Eurasian climate linkage induced by tropical ocean variability. <i>Nature Comm. 10(1)</i>: 8 pp. <a href=\"https://dx.doi.org/10.1038/s41467-019-11359-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-019-11359-7</a>","StandardTitle":"Arctic–Eurasian climate linkage induced by tropical ocean variability","AuthorsString":"Matsumura, S.; Yu, K.","BibLvlCode":"AS"},{"BRefID":334398,"RR":"<b>Terhaar, J.; Lauerwald, R.; Regnier, P.; Gruber, N.; Bopp, L.</b> (2021). Around one third of current Arctic Ocean primary production sustained by rivers and coastal erosion. <i>Nature Comm. 12(1)</i>: 169. <a href=\"https://dx.doi.org/10.1038/s41467-020-20470-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-020-20470-z</a>","StandardTitle":"Around one third of current Arctic Ocean primary production sustained by rivers and coastal erosion","AuthorsString":"Terhaar, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":311224,"RR":"<b>Exton, D.A.; Ahmadia, G.N.; Cullen-Unsworth, L.C.; Jompa, J.; May, D.; Rice, J.; Simonin, P.W.; Unsworth, R.F.K.; Smith, D.J.</b> (2019). Artisanal fish fences pose broad and unexpected threats to the tropical coastal seascape. <i>Nature Comm. 10(1)</i>: 9 pp. <a href=\"https://dx.doi.org/10.1038/s41467-019-10051-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-019-10051-0</a>","StandardTitle":"Artisanal fish fences pose broad and unexpected threats to the tropical coastal seascape","AuthorsString":"Exton, D.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":310866,"RR":"<b>Seitz, K.W.; Dombrowski, N.; Eme, L.; Spang, A.; Lombard, J.; Sieber, J.R.; Teske, A.P.; Ettema, T.J.G.; Baker, B.J.</b> (2019). Asgard archaea capable of anaerobic hydrocarbon cycling. <i>Nature Comm. 10(1)</i>: 1822. <a href=\"https://dx.doi.org/10.1038/s41467-019-09364-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-019-09364-x</a>","StandardTitle":"Asgard archaea capable of anaerobic hydrocarbon cycling","AuthorsString":"Seitz, K.W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":406667,"RR":"<b>Danovaro, R.; Aronson, J.; Bianchelli, S.; Boström, C.; Chen, W.; Cimino, R.; Corinaldesi, C.; Cortina-Segarra, J.; D’Ambrosio, P.; Gambi, C.; Garrabou, J.; Giorgetti, A.; Grehan, A.; Hannachi, A.; Mangialajo, L.; Morato, T.; Orfanidis, S.; Papadopoulou, N.; Ramirez-Llodra, E.; Smith, C. J.; Snelgrove, P.; van de Koppel, J.; van Tatenhove, J.; Fraschetti, S.</b> (2025). Assessing the success of marine ecosystem restoration using meta-analysis. <i>Nature Comm. 16(1)</i>: 3062. <a href=\"https://dx.doi.org/10.1038/s41467-025-57254-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-025-57254-2</a>","StandardTitle":"Assessing the success of marine ecosystem restoration using meta-analysis","AuthorsString":"Danovaro, R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":350637,"RR":"<b>Zhang, Z.; Zhang, Q.; Wang, T.; Xu, N.; Lu, T.; Hong, W.; Peñuelas, J.; Gillings, M.; Wang, M.; Gao, W.; Qian, H.</b> (2022). Assessment of global health risk of antibiotic resistance genes. <i>Nature Comm. 13</i>: 1553. <a href=\"https://dx.doi.org/10.1038/s41467-022-29283-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-022-29283-8</a>","StandardTitle":"Assessment of global health risk of antibiotic resistance genes","AuthorsString":"Zhang, Z. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":363786,"RR":"<b>Chudley, T.R.; Howat, I.M.; King, M.D.; Negrete, A.</b> (2023). Atlantic water intrusion triggers rapid retreat and regime change at previously stable Greenland glacier. <i>Nature Comm. 14(1)</i>: 2151. <a href=\"https://dx.doi.org/10.1038/s41467-023-37764-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-023-37764-7</a>","StandardTitle":"Atlantic water intrusion triggers rapid retreat and regime change at previously stable Greenland glacier","AuthorsString":"Chudley, T.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":368441,"RR":"<b>Nishino, S.; Jung, J.; Cho, K.-H.; Williams, W.J.; Fujiwara, A.; Murata, A.; Itoh, M.; Watanabe, E.; Aoyama, M.; Yamamoto-Kawai, M.; Kikuchi, T.; Yang, E.J.; Kang, S.-H.</b> (2023). Atlantic-origin water extension into the Pacific Arctic induced an anomalous biogeochemical event. <i>Nature Comm. 14(1)</i>: 6235. <a href=\"https://dx.doi.org/10.1038/s41467-023-41960-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-023-41960-w</a>","StandardTitle":"Atlantic-origin water extension into the Pacific Arctic induced an anomalous biogeochemical event","AuthorsString":"Nishino, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":381367,"RR":"<b>Jin, H.; Zhang, C.; Meng, S.; Wang, Q.; Ding, X.; Meng, L.; Zhuang, Y.; Yao, X.; Gao, Y.; Shi, F.; Mock, T.; Gao, H.</b> (2024). Atmospheric deposition and river runoff stimulate the utilization of dissolved organic phosphorus in coastal seas. <i>Nature Comm. 15(1)</i>: 658. <a href=\"https://dx.doi.org/10.1038/s41467-024-44838-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-024-44838-7</a>","StandardTitle":"Atmospheric deposition and river runoff stimulate the utilization of dissolved organic phosphorus in coastal seas","AuthorsString":"Jin, H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":283189,"RR":"<b>Daines, S.J.; Mills, B.J.W.; Lenton, T.M.</b> (2017). Atmospheric oxygen regulation at low Proterozoic levels by incomplete oxidative weathering of sedimentary organic carbon. <i>Nature Comm. 8(14379)</i>: 11 pp. <a href=\"http://dx.doi.org/10.1038/ncomms14379\" target=\"_blank\">http://dx.doi.org/10.1038/ncomms14379</a>","StandardTitle":"Atmospheric oxygen regulation at low Proterozoic levels by incomplete oxidative weathering of sedimentary organic carbon","AuthorsString":"Daines, S.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":381181,"RR":"<b>Mahendrarajah, T.A.; Moody, E.R.R.; Schrempf, D.; Szánthó, L.L.; Dombrowski, N.; Davín, A.A.; Pisani, D.; Donoghue, P.C.J.; Szöllosi, G.J.; Williams, T.A.; Spang, A.</b> (2023). ATP synthase evolution on a cross-braced dated tree of life. <i>Nature Comm. 14(1)</i>: 7456. <a href=\"https://dx.doi.org/10.1038/s41467-023-42924-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-023-42924-w</a>","StandardTitle":"ATP synthase evolution on a cross-braced dated tree of life","AuthorsString":"Mahendrarajah, T.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":330140,"RR":"<b>Killingsworth, B.A.; Sansjofre, P.; Philippot, P.; Cartigny, P.; Thomazo, C.; Lalonde, S.V.</b> (2020). Author Correction: Constraining the rise of oxygen with oxygen isotopes. <i>Nature Comm. 11(1)</i>: 1 pp. <a href=\"https://dx.doi.org/10.1038/s41467-020-18888-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-020-18888-6</a>","StandardTitle":"Author Correction: Constraining the rise of oxygen with oxygen isotopes","AuthorsString":"Killingsworth, B.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296532,"RR":"<b>Mignot, A.; Ferrari, R.; Claustre, H.</b> (2018). Author Correction: Floats with bio-optical sensors reveal what processes trigger the North Atlantic bloom. <i>Nature Comm. 9(1)</i>: 1 pp. <a href=\"https://dx.doi.org/10.1038/s41467-018-04181-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-018-04181-0</a>","StandardTitle":"Author Correction: Floats with bio-optical sensors reveal what processes trigger the North Atlantic bloom","AuthorsString":"Mignot, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":362986,"RR":"<b>Nielsen, E.E.; Cariani, A.; Aoidh, E.M.; Maes, G.E.; Milano, I.; Ogden, R.; Taylor, M.; Hemmer-Hansen, J.; Babbucci, M.; Bargelloni, L.; Bekkevold, D.; Diopere, E.; Grenfell, L.; Helyar, S.; Limborg, M.T.; Martinsohn, J.T.; McEwing, R.; Panitz, F.; Patarnello, T.; Tinti, F.; Van Houdt, J.K.J.; Volckaert, F.A.M.; Waples, R.S.; FishPopTrace Consortium; Carvalho, G.R.</b> (2019). Author correction: gene-associated markers provide tools for tackling illegal fishing and false eco-certification. <i>Nature Comm. 10</i>: 5325. <a href=\"https://dx.doi.org/10.1038/s41467-019-13399-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-019-13399-5</a>","StandardTitle":"Author correction: gene-associated markers provide tools for tackling illegal fishing and false eco-certification","AuthorsString":"Nielsen, E.E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296647,"RR":"<b>Safaie, A.; Silbiger, N.J.; McClanahan, T.R.; Pawlak, G.; Barshis, D.J.; Hench, J.L.; Rogers, J.S.; Williams, G.J.; Davis, K.A.</b> (2018). Author Correction: High frequency temperature variability reduces the risk of coral bleaching. <i>Nature Comm. 9(1)</i>: 1 pp. <a href=\"https://dx.doi.org/10.1038/s41467-018-04741-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-018-04741-4</a>","StandardTitle":"Author Correction: High frequency temperature variability reduces the risk of coral bleaching","AuthorsString":"Safaie, A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":297061,"RR":"<b>Zhao, J.; Bower, A.; Yang, J.; Lin, X.</b> (2018). Author Correction: Meridional heat transport variability induced by mesoscale processes in the subpolar North Atlantic. <i>Nature Comm. 9(1)</i>: 1. <a href=\"https://dx.doi.org/10.1038/s41467-018-04809-1\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-018-04809-1</a>","StandardTitle":"Author Correction: Meridional heat transport variability induced by mesoscale processes in the subpolar North Atlantic","AuthorsString":"Zhao, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":292340,"RR":"<b>Tamsitt, V.; Drake, H.F.; Morrison, A.K.; Talley, L.D.; Dufour, C.O.; Gray, A.R.; Griffies, S.M.; Mazloff, M.R.; Sarmiento, J.L.; Wang, J.; Weijer, W.</b> (2018). Author Correction: Spiraling pathways of global deep waters to the surface of the Southern Ocean. <i>Nature Comm. 9(1)</i>: 1 pp. <a href=\"https://dx.doi.org/10.1038/s41467-017-02105-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-017-02105-y</a>","StandardTitle":"Author Correction: Spiraling pathways of global deep waters to the surface of the Southern Ocean","AuthorsString":"Tamsitt, V. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":362786,"RR":"<b>Osuna-Cruz, C.M.; Bilcke, G.; Vancaester, E.; De Decker, S.; Bones, A.M.; Winge, P.; Poulsen, N.; Bulankova, P.; Verhelst, B.; Audoor, S.; Belisova, D.; Pargana, A.; Russo, M.; Stock, F.; Cirri, E.; Brembu, T.; Pohnert, G.; Piganeau, G.; Ferrante, M.I.; Mock, T.; Sterck, L.; Sabbe, K.; De Veylder, L.; Vyverman, W.; Vandepoele, K.</b> (2020). Author correction: The <i>Seminavis robusta</i> genome provides insights into the evolutionary adaptations of benthic diatoms. <i>Nature Comm. 11</i>: 5331. <a href=\"https://dx.doi.org/10.1038/s41467-020-19222-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-020-19222-w</a>","StandardTitle":"Author correction: The <i>Seminavis robusta</i> genome provides insights into the evolutionary adaptations of benthic diatoms","AuthorsString":"Osuna-Cruz, C.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":318291,"RR":"<b>Cavan, E.L.; Belcher, A.; Atkinson, A.; Hill, S.L.; Kawaguchi, S.; McCormack, S.; Meyer, B.; Nicol, S.; Ratnarajah, L.; Schmidt, K.; Steinberg, D.K.; Tarling, G.A.; Boyd, P.W.</b> (2019). Author Correction: The importance of Antarctic krill in biogeochemical cycles. <i>Nature Comm. 10(1)</i>: 1. <a href=\"https://dx.doi.org/10.1038/s41467-019-13390-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-019-13390-0</a>","StandardTitle":"Author Correction: The importance of Antarctic krill in biogeochemical cycles","AuthorsString":"Cavan, E.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":302864,"RR":"<b>Trumble, S.J.; Norman, S.A.; Crain, D.D.; Mansouri, F.; Winfield, Z.C.; Sabin, R.; Potter, C.W.; Gabriele, C.M.; Usenko, S.</b> (2018). Baleen whale cortisol levels reveal a physiological response to 20th century whaling. <i>Nature Comm. 9(1)</i>: 8 pp. <a href=\"https://dx.doi.org/10.1038/s41467-018-07044-w\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-018-07044-w</a>","StandardTitle":"Baleen whale cortisol levels reveal a physiological response to 20th century whaling","AuthorsString":"Trumble, S.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":354192,"RR":"<b>Yamagami, Y.; Watanabe, M.; Mori, M.; Ono, J.</b> (2022). Barents-Kara sea-ice decline attributed to surface warming in the Gulf Stream. <i>Nature Comm. 13(1)</i>: 3767. <a href=\"https://dx.doi.org/10.1038/s41467-022-31117-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-022-31117-6</a>","StandardTitle":"Barents-Kara sea-ice decline attributed to surface warming in the Gulf Stream","AuthorsString":"Yamagami, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":295110,"RR":"<b>Martinez-Ruiz, F.; Jroundi, F.; Paytan, A.; Guerra-Tschuschke, I.; Abad, M.d.M.; González-Muñoz, M.T.</b> (2018). Barium bioaccumulation by bacterial biofilms and implications for Ba cycling and use of Ba proxies. <i>Nature Comm. 9(1)</i>: 9 pp. <a href=\"https://dx.doi.org/10.1038/s41467-018-04069-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-018-04069-z</a>","StandardTitle":"Barium bioaccumulation by bacterial biofilms and implications for Ba cycling and use of Ba proxies","AuthorsString":"Martinez-Ruiz, F. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":308728,"RR":"<b>Rohith, B.; Paul, A.; Durand, F.; Testut, L.; Prema, S.; Afroosa, M.; Ramakrishna, S.S.V.S.; Shenoi, S.S.C.</b> (2019). Basin-wide sea level coherency in the tropical Indian Ocean driven by Madden–Julian Oscillation. <i>Nature Comm. 10(1)</i>: 9 pp. <a href=\"https://dx.doi.org/10.1038/s41467-019-09243-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-019-09243-5</a>","StandardTitle":"Basin-wide sea level coherency in the tropical Indian Ocean driven by Madden–Julian Oscillation","AuthorsString":"Rohith, B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392476,"RR":"<b>Duque Londono, C.; Cones, S.F.; Deng, J.; Wu, J.; Yuk, H.; Guza, D.E.; Mooney, T.A.; Zhao, X.</b> (2024). Bioadhesive interface for marine sensors on diverse soft fragile species. <i>Nature Comm. 15(1)</i>: 2958 . <a href=\"https://dx.doi.org/10.1038/s41467-024-46833-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-024-46833-4</a>","StandardTitle":"Bioadhesive interface for marine sensors on diverse soft fragile species","AuthorsString":"Duque Londono, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":355297,"RR":"<b>Busch, K.; Slaby, B.M.; Bach, W.; Boetius, A.; Clefsen, I.; Colaço, A.; Creemers, M.; Cristobo, J.; Federwisch, L.; Franke, A.; Gavriilidou, A.; Hethke, A.; Kenchington, E.; Mienis, F.; Mills, S.; Riesgo, A.; Ríos, P.; Roberts, E.M.; Sipkema, D.; Pita, L.; Schupp, P.J.; Xavier, J.; Rapp, H.T.; Hentschel, U.</b> (2022). Biodiversity, environmental drivers, and sustainability of the global deep-sea sponge microbiome. <i>Nature Comm. 13</i>: 5160. <a href=\"https://dx.doi.org/10.1038/s41467-022-32684-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-022-32684-4</a>","StandardTitle":"Biodiversity, environmental drivers, and sustainability of the global deep-sea sponge microbiome","AuthorsString":"Busch, K. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":259127,"RR":"<b>Gottschalk, J.; Skinner, L.C.; Lippold, J.; Vogel, H.; Frank, N.; Jaccard, S.L.; Waelbroeck, C.</b> (2016). Biological and physical controls in the Southern Ocean on past millennial-scale atmospheric CO<sub>2</sub> changes. <i>Nature Comm. 7(11539)</i>: 11 pp. <a href=\"http://dx.doi.org/10.1038/ncomms11539\" target=\"_blank\">http://dx.doi.org/10.1038/ncomms11539</a>","StandardTitle":"Biological and physical controls in the Southern Ocean on past millennial-scale atmospheric CO<sub>2</sub> changes","AuthorsString":"Gottschalk, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":325556,"RR":"<b>Mat, A.M.; Sarrazin, J.; Markov, G.V.; Apremont, V.; Dubreuil, C.; Eché, C.; Fabioux, C.; Klopp, C.; Sarradin, P.-M.; Tanguy, A.; Huvet, A.; Matabos, M.</b> (2020). Biological rhythms in the deep-sea hydrothermal mussel <i>Bathymodiolus azoricus</i>. <i>Nature Comm. 11(1)</i>: 12 pp. <a href=\"https://dx.doi.org/10.1038/s41467-020-17284-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-020-17284-4</a>","StandardTitle":"Biological rhythms in the deep-sea hydrothermal mussel <i>Bathymodiolus azoricus</i>","AuthorsString":"Mat, A.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":353525,"RR":"<b>Rumney, R.M.H.; Robson, S.C.; Kao, A.P.; Barbu, E.; Bozycki, L.; Smith, J.R.; Cragg, S.M.; Couceiro, F.; Parwani, R.; Tozzi, G.; Stuer, M.; Barber, A.H.; Ford, A.T.; Górecki, D.C.</b> (2022). 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Recent trend reversal for declining European seagrass meadows. <i>Nature Comm. 10(1)</i>: 1-8. <a href=\"https://dx.doi.org/10.1038/s41467-019-11340-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-019-11340-4</a>","StandardTitle":"Recent trend reversal for declining European seagrass meadows","AuthorsString":"de los Santos, Carmen B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":349148,"RR":"<b>Li, Z.; Ding, Q.; Steele, M.; Schweiger, A.</b> (2022). Recent upper Arctic Ocean warming expedited by summertime atmospheric processes. <i>Nature Comm. 13(1)</i>: 362. <a href=\"https://dx.doi.org/10.1038/s41467-022-28047-8\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-022-28047-8</a>","StandardTitle":"Recent upper Arctic Ocean warming expedited by summertime atmospheric processes","AuthorsString":"Li, Z. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":334399,"RR":"<b>Wang, J.; Church, J.A.; Zhang, X.; Chen, X.</b> (2021). Reconciling global mean and regional sea level change in projections and observations. <i>Nature Comm. 12(1)</i>: 990. <a href=\"https://dx.doi.org/10.1038/s41467-021-21265-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-021-21265-6</a>","StandardTitle":"Reconciling global mean and regional sea level change in projections and observations","AuthorsString":"Wang, J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":381144,"RR":"<b>Hou, S.; Stap, L.B.; Paul, R.; Nelissen, M.; Hoem, F.S.; Ziegler, M.; Sluijs, A.; Sangiorgi, F.; Bijl, P.K.</b> (2023). Reconciling Southern Ocean fronts equatorward migration with minor Antarctic ice volume change during Miocene cooling. <i>Nature Comm. 14(1)</i>: 7230. <a href=\"https://dx.doi.org/10.1038/s41467-023-43106-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-023-43106-4</a>","StandardTitle":"Reconciling Southern Ocean fronts equatorward migration with minor Antarctic ice volume change during Miocene cooling","AuthorsString":"Hou, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392477,"RR":"<b>Smetacek, V.; Fernández-Méndez, M.; Pausch, F.; Wu, J.</b> (2024). Rectifying misinformation on the climate intervention potential of ocean afforestation. <i>Nature Comm. 15(1)</i>: 3012. <a href=\"https://dx.doi.org/10.1038/s41467-024-47134-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-024-47134-6</a>","StandardTitle":"Rectifying misinformation on the climate intervention potential of ocean afforestation","AuthorsString":"Smetacek, V. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":290657,"RR":"<b>Rafter, P.A.; Sigman, D.M.; Mackey, K.R.M.</b> (2017). Recycled iron fuels new production in the eastern equatorial Pacific Ocean. <i>Nature Comm. 8(1)</i>: 10 pp. <a href=\"https://dx.doi.org/10.1038/s41467-017-01219-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-017-01219-7</a>","StandardTitle":"Recycled iron fuels new production in the eastern equatorial Pacific Ocean","AuthorsString":"Rafter, P.A. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":288954,"RR":"<b>Cai, W.-J.; Huang, W.J.; Luther III, G.W.; Pierrot, D.; Li, M.; Testa, J.; Xue, M.; Joesoef, A.; Mann, R.; Brodeur, J.; Xu, Y.-Y.; Chen, B.; Hussain, N.; Waldbusser, G.G.; Cornwell, J.; Kemp, M.</b> (2017). Redox reactions and weak buffering capacity lead to acidification in the Chesapeake Bay. <i>Nature Comm. 8(1)</i>: 12 pp. <a href=\"https://dx.doi.org/10.1038/s41467-017-00417-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-017-00417-7</a>","StandardTitle":"Redox reactions and weak buffering capacity lead to acidification in the Chesapeake Bay","AuthorsString":"Cai, W.-J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":323859,"RR":"<b>Zou, S.; Bower, A.; Furey, H.; Susan Lozier, M.; Xu, X.</b> (2020). Redrawing the Iceland−Scotland Overflow Water pathways in the North Atlantic. <i>Nature Comm. 11(1)</i>: 8 pp. <a href=\"https://dx.doi.org/10.1038/s41467-020-15513-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-020-15513-4</a>","StandardTitle":"Redrawing the Iceland−Scotland Overflow Water pathways in the North Atlantic","AuthorsString":"Zou, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":282620,"RR":"<b>Calosi, P.; Melatunan, S.; Turner, L.M.; Artioli, Y.; Davidson, R.L.; Byrne, J.J.; Viant, M.R.; Widdicombe, S.; Rundle, S.D.</b> (2017). Regional adaptation defines sensitivity to future ocean acidification. <i>Nature Comm. 8(13994)</i>: 10 pp. <a href=\"http://dx.doi.org/10.1038/ncomms13994\" target=\"_blank\">http://dx.doi.org/10.1038/ncomms13994</a>","StandardTitle":"Regional adaptation defines sensitivity to future ocean acidification","AuthorsString":"Calosi, P. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":365468,"RR":"<b>Zhao, Q.; Van den Brink, P.J.; Xu, C.; Wang, S.; Clark, A.T.; Karakoç, C.; Sugihara, G.; Widdicombe, C.E.; Atkinson, A.; Matsuzaki, S.S.; Shinohara, R.; He, S.; Wang, Y.X.G.; De Laender, F.</b> (2023). Relationships of temperature and biodiversity with stability of natural aquatic food webs. <i>Nature Comm. 14(1)</i>: 3507. <a href=\"https://dx.doi.org/10.1038/s41467-023-38977-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-023-38977-6</a>","StandardTitle":"Relationships of temperature and biodiversity with stability of natural aquatic food webs","AuthorsString":"Zhao, Q. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":329235,"RR":"<b>Nath, N.; Fuentes-Monteverde, J.C.; Pech-Puch, D.; Rodríguez, J.; Jimenez, C.; Noll, M.; Kreiter, A.; Reggelin, M.; Navarro-Vázquez, A.; Griesinger, C.</b> (2020). Relative configuration of micrograms of natural compounds using proton residual chemical shift anisotropy. <i>Nature Comm. 11(1)</i>: 9 pp. <a href=\"https://dx.doi.org/10.1038/s41467-020-18093-5\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-020-18093-5</a>","StandardTitle":"Relative configuration of micrograms of natural compounds using proton residual chemical shift anisotropy","AuthorsString":"Nath, N. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":284058,"RR":"<b>Cavan, E.L.; Trimmer, M.; Shelley, F.; Sanders, R.</b> (2017). Remineralization of particulate organic carbon in an ocean oxygen minimum zone. <i>Nature Comm. 8(14847 )</i>: 9 pp. <a href=\"https://dx.doi.org/10.1038/ncomms14847\" target=\"_blank\">https://dx.doi.org/10.1038/ncomms14847</a>","StandardTitle":"Remineralization of particulate organic carbon in an ocean oxygen minimum zone","AuthorsString":"Cavan, E.L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":325291,"RR":"<b>Moreau, S.; Boyd, P.W.; Strutton, P.G.</b> (2020). Remote assessment of the fate of phytoplankton in the Southern Ocean sea-ice zone. <i>Nature Comm. 11(1)</i>: 9 pp. <a href=\"https://dx.doi.org/10.1038/s41467-020-16931-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-020-16931-0</a>","StandardTitle":"Remote assessment of the fate of phytoplankton in the Southern Ocean sea-ice zone","AuthorsString":"Moreau, S.; Boyd, P.W.; Strutton, P.G.","BibLvlCode":"AS"},{"BRefID":359028,"RR":"<b>Pang, C.; Nikurashin, M.; Peña-Molino, B.; Sloyan, B.M.</b> (2022). Remote energy sources for mixing in the Indonesian Seas. <i>Nature Comm. 13(1)</i>: 6535. <a href=\"https://dx.doi.org/10.1038/s41467-022-34046-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-022-34046-6</a>","StandardTitle":"Remote energy sources for mixing in the Indonesian Seas","AuthorsString":"Pang, C. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":317038,"RR":"<b>Bendif, E.M.; Nevado, B.; Wong, E.L.Y.; Hagino, K.; Probert, I.; Young, J.R.; Rickaby, R.E.M.; Filatov, D.A.</b> (2019). Repeated species radiations in the recent evolution of the key marine phytoplankton lineage <i>Gephyrocapsa</i>. <i>Nature Comm. 10(1)</i>: 9 pp. <a href=\"https://dx.doi.org/10.1038/s41467-019-12169-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-019-12169-7</a>","StandardTitle":"Repeated species radiations in the recent evolution of the key marine phytoplankton lineage <i>Gephyrocapsa</i>","AuthorsString":"Bendif, E.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":313226,"RR":"<b>Costello, M.J.; Tsai, P.; Cheung, A.K.L.; Basher, Z.; Chaudhary, C.</b> (2018). Reply to ‘Dissimilarity measures affected by richness differences yield biased delimitations of biogeographic realms’. <i>Nature Comm. 9(1)</i>: 5085. <a href=\"https://dx.doi.org/10.1038/s41467-018-07252-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-018-07252-4</a>","StandardTitle":"Reply to ‘Dissimilarity measures affected by richness differences yield biased delimitations of biogeographic realms’","AuthorsString":"Costello, M.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":261243,"RR":"<b>Liu, W.; Xie, S.-P.; Lu, J.</b> (2016). 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Reply to: “Questions remain about the biolability of dissolved black carbon along the combustion continuum”. <i>Nature Comm. 12(1)</i>: 4282. <a href=\"https://dx.doi.org/10.1038/s41467-021-24478-x\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-021-24478-x</a>","StandardTitle":"Reply to: “Questions remain about the biolability of dissolved black carbon along the combustion continuum”","AuthorsString":"Qi, Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":353214,"RR":"<b>Sharko, F.S.; Rastorguev, S.M.; Tikhonov, A.N.; Nedoluzhko, A.V.</b> (2022). 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Reply to: Caution in inferring viral strategies from abundance correlations in marine metagenomes. <i>Nature Comm. 10(1)</i>: 502. <a href=\"https://dx.doi.org/10.1038/s41467-018-08286-4\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-018-08286-4</a>","StandardTitle":"Reply to: Caution in inferring viral strategies from abundance correlations in marine metagenomes","AuthorsString":"Coutinho, F.H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359801,"RR":"<b>Liu, Y.-W.; Eagle, R.A.; Aciego, S.M.; Gilmore, R.E.; Ries, J.B.</b> (2022). Reply to: Re-examining extreme carbon isotope fractionation in the coccolithophore <i>Ochrosphaera neapolitana</i>. <i>Nature Comm. 13(1)</i>: 7605. <a href=\"https://dx.doi.org/10.1038/s41467-022-35207-3\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-022-35207-3</a>","StandardTitle":"Reply to: Re-examining extreme carbon isotope fractionation in the coccolithophore <i>Ochrosphaera neapolitana</i>","AuthorsString":"Liu, Y.-W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359052,"RR":"<b>Gowan, E.J.; Zhang, X.; Khosravi, S.; Rovere, A.; Stocchi, P.; Hughes, A.L.C.; Gyllencreutz, R.; Mangerud, J.; Svendsen, J.-I.; Lohmann, G.</b> (2022). 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Resolving the structure of phage–bacteria interactions in the context of natural diversity. <i>Nature Comm. 13(1)</i>: 372. <a href=\"https://dx.doi.org/10.1038/s41467-021-27583-z\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-021-27583-z</a>","StandardTitle":"Resolving the structure of phage–bacteria interactions in the context of natural diversity","AuthorsString":"Kauffman, K.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":393153,"RR":"<b>Hsu, T.-Y.; Mazloff, M.R.; Gille, S.T.; Freilich, M.A.; Sun, R.; Cornuelle, B.D.</b> (2024). Response of sea surface temperature to atmospheric rivers. <i>Nature Comm. 15(1)</i>: 5018. <a href=\"https://dx.doi.org/10.1038/s41467-024-48486-9\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-024-48486-9</a>","StandardTitle":"Response of sea surface temperature to atmospheric rivers","AuthorsString":"Hsu, T.-Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":392475,"RR":"<b>Hu, N.; Bourdeau, P.E.; Hollander, J.</b> (2024). 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Return of naturally sourced Pb to Atlantic surface waters. <i>Nature Comm. 7(12921)</i>: 12 pp. <a href=\"http://dx.doi.org/10.1038/ncomms12921\" target=\"_blank\">dx.doi.org/10.1038/ncomms12921</a>","StandardTitle":"Return of naturally sourced Pb to Atlantic surface waters","AuthorsString":"Bridgestock, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":350976,"RR":"<b>Selig, E.R.; Nakayama, S.; Wabnitz, C.C.C.; Österblom, H.; Spijkers, J.; Miller, N.A.; Bebbington, J.; Decker Sparks, J.L.</b> (2022). Revealing global risks of labor abuse and illegal, unreported, and unregulated fishing. <i>Nature Comm. 13</i>: 1612. <a href=\"https://dx.doi.org/10.1038/s41467-022-28916-2\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-022-28916-2</a>","StandardTitle":"Revealing global risks of labor abuse and illegal, unreported, and unregulated fishing","AuthorsString":"Selig, E.R. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":329237,"RR":"<b>Watson, A.J.; Schuster, U.; Shutler, J.D.; Holding, T.; Ashton, I.G.C.; Landschützer, P.; Woolf, D.K.; Goddijn-Murphy, L.</b> (2020). 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Revisiting the distribution of oceanic N<sub>2</sub> fixation and estimating diazotrophic contribution to marine production. <i>Nature Comm. 10(1)</i>: 10 pp. <a href=\"https://dx.doi.org/10.1038/s41467-019-08640-0\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-019-08640-0</a>","StandardTitle":"Revisiting the distribution of oceanic N<sub>2</sub> fixation and estimating diazotrophic contribution to marine production","AuthorsString":"Tang, W. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":359805,"RR":"<b>Cornish, S.B.; Johnson, H.L.; Mallett, R.D.C.; Dörr, J.; Kostov, Y.; Richards, A.E.</b> (2022). Rise and fall of sea ice production in the Arctic Ocean’s ice factories. <i>Nature Comm. 13(1)</i>: 7800. <a href=\"https://dx.doi.org/10.1038/s41467-022-34785-6\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-022-34785-6</a>","StandardTitle":"Rise and fall of sea ice production in the Arctic Ocean’s ice factories","AuthorsString":"Cornish, S.B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":437337,"RR":"<b>Wang, Q.; Liu, K.; Wang, M.; Zhang, Z.; Chen, H.; Liu, L.; Wu, J.; Zheng, H.</b> (2026). 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Role of atmospheric rivers in shaping long term Arctic moisture variability. <i>Nature Comm. 15(1)</i>. <a href=\"https://dx.doi.org/10.1038/s41467-024-49857-y\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-024-49857-y</a>","StandardTitle":"Role of atmospheric rivers in shaping long term Arctic moisture variability","AuthorsString":"Wang, Z.B. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":361069,"RR":"<b>Décima, M.; Stukel, M.R.; Nodder, S.D.; Gutiérrez-Rodríguez, A.; Selph, K.E.; dos Santos, A.L.; Safi, K.; Kelly, T.B.; Deans, F.; Morales, S.E.; Baltar, F.; Latasa, M.; Gorbunov, M.Y.; Pinkerton, M.</b> (2023). 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Substantial oxygen consumption by aerobic nitrite oxidation in oceanic oxygen minimum zones. <i>Nature Comm. 12(1)</i>: 7043. <a href=\"https://dx.doi.org/10.1038/s41467-021-27381-7\" target=\"_blank\">https://dx.doi.org/10.1038/s41467-021-27381-7</a>","StandardTitle":"Substantial oxygen consumption by aerobic nitrite oxidation in oceanic oxygen minimum zones","AuthorsString":"Beman, J.M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":325567,"RR":"<b>Zheng, Z.-Z.; Zheng, L.-W.; Xu, M.N.; Tan, E.; Hutchins, D.A.; Deng, W.; Zhang, Y.; Shi, D.; Dai, M.; Kao, S.-J.</b> (2020). 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