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Rapid increases in satellite-observed ice sheet surface meltwater production. Nat. Clim. Chang. 15(7): 769-774. https://dx.doi.org/10.1038/s41558-025-02364-4","PeerRev":1},{"BRefID":367638,"RR":"Box, J.E.; Nielsen, K.P.; Yang, X.; Niwano, M.; Wehrlé, A.; van As, D.; Fettweis, X.; Køltzow, M.A.Ø.; Palmason, B.; Fausto, R.S.; van den Broeke, M.R.; Huai, B.; Ahlstrom, A.P.; Langley, K.; Dachauer, A.; Noël, B. (2023). Greenland ice sheet rainfall climatology, extremes and atmospheric river rapids. Meteorol. Appl. 30(4): e2134. https://dx.doi.org/10.1002/met.2134","PeerRev":1},{"BRefID":382722,"RR":"Gorodetskaya, I.V.; Duran-Alarcon, C.; Gonzalez-Herrero, S.; Clem, K.R.; Zou, X.; Rowe, P.; Imazio, P.R.; Campos, D.; Leroy-Dos Santos, C.L.D.; Dutrievoz, N.; Wille, J.D.; Chyhareva, A.; Favier, V.; Blanchet, J.; Pohl, B.; Cordero, R.R.; Park, S.J.; Colwell, S.; Lazzara, M.A.; Carrasco, J.; Gulisano, A.M.; Krakovska, S.; Ralph, F.M.; Dethinne, T.; Picard, G. (2023). Record-high Antarctic Peninsula temperatures and surface melt in February 2022: a compound event with an intense atmospheric river. npj Climate and Atmospheric Science 6(1): 202. https://dx.doi.org/10.1038/s41612-023-00529-6","PeerRev":1},{"BRefID":382847,"RR":"Kochtitzky, W.; Copland, L.; King, M.; Hugonnet, R.; Jiskoot, H.; Morlighem, M.; Millan, R.; Khan, S.A.; Noël, B. (2023). Closing Greenland's mass balance: frontal ablation of every Greenlandic glacier from 2000 to 2020. Geophys. Res. Lett. 50(17): e2023GL104095. https://dx.doi.org/10.1029/2023GL104095","PeerRev":1},{"BRefID":369516,"RR":"Noël, B.; Van Wessem, J.M.; Wouters, B.; Trusel, L.; Lhermitte, S.; van den Broeke, M.R. (2023). Higher Antarctic ice sheet accumulation and surface melt rates revealed at 2 km resolution. Nature Comm. 14(1): 7949. https://dx.doi.org/10.1038/s41467-023-43584-6","PeerRev":1},{"BRefID":391450,"RR":"Seehaus, T.; Sommer, C.; Dethinne, T.; Malz, P. (2023). Mass changes of the northern Antarctic Peninsula Ice Sheet derived from repeat bi-static synthetic aperture radar acquisitions for the period 2013-2017. Cryosphere 17(11): 4629-4644. https://dx.doi.org/10.5194/tc-17-4629-2023","PeerRev":1},{"BRefID":391435,"RR":"Tedesco, M.; Colosio, P.; Fettweis, X.; Cervone, G. (2023). A computationally efficient statistically downscaled 100 m resolution Greenland product from the regional climate model MAR. Cryosphere 17(12): 5061-5074. https://dx.doi.org/10.5194/tc-17-5061-2023","PeerRev":1},{"BRefID":355448,"RR":"Box, J.E.; Hubbard, A.; Bahr, D.B.; Colgan, W.T.; Fettweis, X.; Mankoff, K.D.; Wehrlé, A.; Noël, B.; van den Broeke, M.R.; Wouters, B.; Björk, A.A.; Fausto, R.S. (2022). Greenland ice sheet climate disequilibrium and committed sea-level rise. Nat. Clim. Chang. 12(9): 808-813. https://dx.doi.org/10.1038/s41558-022-01441-2","PeerRev":1},{"BRefID":361566,"RR":"Carter, J.; Leeson, A.; Orr, A.; Kittel, C.; van Wessem, J.M. (2022). Variability in Antarctic surface climatology across regional climate models and reanalysis datasets. Cryosphere 16(9): 3815-3841. https://dx.doi.org/10.5194/tc-16-3815-2022","PeerRev":1},{"BRefID":352731,"RR":"Hansen, N.; Simonsen, S.B.; Boberg, F.; Kittel, C.; Orr, A.; Souverijns, N.; Van Wessem, J.M.; Mottram, R. (2022). Brief communication: Impact of common ice mask in surface mass balance estimates over the Antarctic ice sheet. Cryosphere 16(2): 711-718. https://dx.doi.org/10.5194/tc-16-711-2022","PeerRev":1},{"BRefID":352789,"RR":"Huot, P.-V.; Kittel, C.; Fichefet, T.; Jourdain, N.C.; Fettweis, X. (2022). Effects of ocean mesoscale eddies on atmosphere-sea ice-ocean interactions off Adelie Land, East Antarctica. Clim. Dyn. 59: 41-60. https://dx.doi.org/10.1007/s00382-021-06115-x","PeerRev":1},{"BRefID":382996,"RR":"Kochtitzky, W.; Copland, L.; Van Wychen, W.; Hock, R.; Rounce, D.R.; Jiskoot, H.; Scambos, T.A.; Morlighem, M.; King, M.; Cha, L.; Gould, L.; Merrill, P.M.; Glazovsky, A.; Hugonnet, R.; Strozzi, T.; Noel, B.; Navarro, F.; Millan, R.; Dowdeswell, J.A.; Cook, A.; Dalton, A.; Khan, S.; Jania, J. (2022). Progress toward globally complete frontal ablation estimates of marine-terminating glaciers. Ann. Glaciol. 63(87-89): 143-152. https://dx.doi.org/10.1017/aog.2023.35","PeerRev":1},{"BRefID":352785,"RR":"Pelletier, C.; Fichefet, T.; Goosse, H.; Haubner, K.; Helsen, S.; Huot, P.-V.; Kittel, C.; Klein, F.; Le Clec'h, S.; van Lipzig, N.P.M.; Marchi, S.; Massonnet, F.; Mathiot, P.; Moravveji, E.; Moreno-Chamarro, E.; Ortega, P.; Pattyn, F.; Souverijns, N.; Van Achter, G.; Vanden Broucke, S.; Vanhulle, A.; Verfaillie, D.; Zipf, L. (2022). PARASO, a circum-Antarctic fully coupled ice-sheet-ocean-sea-ice-atmosphere-land model involving f.ETISh1.7, NEMO3.6, LIM3.6, COSM05.0 and CLM4.5. Geosci. Model Dev. 15(2): 553-594. https://dx.doi.org/10.5194/gmd-15-553-2022","PeerRev":1},{"BRefID":350431,"RR":"Sasgen, I.; Salles, A.; Wegmann, M.; Wouters, B.; Fettweis, X.; Noël, B.P.Y.; Beck, C. (2022). Arctic glaciers record wavier circumpolar winds. Nat. Clim. Chang. 12(3): 249-255. https://dx.doi.org/10.1038/s41558-021-01275-4","PeerRev":1},{"BRefID":352514,"RR":"Wille, J.D.; Favier, V.; Jourdain, N.C.; Kittel, C.; Turton, J.V.; Agosta, C.; Gorodetskaya, I.V.; Picard, G.; Codron, F.; Leroy-Dos Santos, C.; Amory, C.; Fettweis, X.; Blanchet, J.; Jomelli, V.; Berchet, A. (2022). Intense atmospheric rivers can weaken ice shelf stability at the Antarctic Peninsula. Commun. Earth Environ. 3: 90. https://dx.doi.org/10.1038/s43247-022-00422-9","PeerRev":1},{"BRefID":353198,"RR":"Crockart, C.K.; Vance, T.R.; Fraser, A.D.; Abram, N.J.; Criscitiello, A.S.; Curran, M.A.J.; Favier, V.; Gallant, A.J.E.; Kittel, C.; Kjaer, H.A.; Klekociuk, A.R.; Jong, L.M.; Moy, A.D.; Plummer, C.T.; Vallelonga, P.T.; Wille, J.; Zhang, L. (2021). El Niño–Southern Oscillation signal in a new East Antarctic ice core, Mount Brown South. Clim. Past 17(5): 1795-1818. https://dx.doi.org/10.5194/cp-17-1795-2021","PeerRev":1},{"BRefID":352971,"RR":"Diener, T.; Sasgen, I.; Agosta, C.; Fürst, J.J.; Braun, M.H.; Konrad, H.; Fettweis, X. (2021). Acceleration of dynamic ice loss in Antarctica from satellite gravimetry. Front. 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(2021). Projected land ice contributions to twenty-first-century sea level rise. Nature (Lond.) 593(7857): 74-82. https://hdl.handle.net/10.1038/s41586-021-03302-y","PeerRev":1},{"BRefID":353635,"RR":"Gilbert, E.; Kittel, C. (2021). Surface melt and runoff on Antarctic ice shelves at 1.5°C, 2°C, and 4°C of future warming. Geophys. Res. Lett. 48(8): e2020GL091733. https://dx.doi.org/10.1029/2020GL091733","PeerRev":1},{"BRefID":354018,"RR":"Huot, P.-V.; Fichefet, T.; Jourdain, N.C.; Mathiot, P.; Rousset, C.; Kittel, C.; Fettweis, X. (2021). Influence of ocean tides and ice shelves on ocean-ice interactions and dense shelf water formation in the D'Urville Sea, Antarctica. Ocean Modelling 162: 101794. https://dx.doi.org/10.1016/j.ocemod.2021.101794","PeerRev":1},{"BRefID":353031,"RR":"Huot, P.-V.; Kittel, C.; Fichefet, T.; Jourdain, N.C.; Sterlin, J.; Fettweis, X. (2021). Effects of the atmospheric forcing resolution on simulated sea ice and polynyas off Adelie Land, East Antarctica. Ocean Modelling 168: 101901. https://dx.doi.org/10.1016/j.ocemod.2021.101901","PeerRev":1},{"BRefID":337282,"RR":"Kittel, C.; Amory, C.; Agosta, C.; Jourdain, N.C.; Hofer, S.; Delhasse, A.; Doutreloup, S.; Huot, P.-V.; Lang, C.; Fichefet, T.; Fettweis, X. (2021). Diverging future surface mass balance between the Antarctic ice shelves and grounded ice sheet. Cryosphere 15(3): 1215-1236. https://hdl.handle.net/10.5194/tc-15-1215-2021","PeerRev":1},{"BRefID":353323,"RR":"Le Toumelin, L.; Amory, C.; Favier, V.; Kittel, C.; Hofer, S.; Fettweis, X.; Gallee, H.; Kayetha, V. (2021). Sensitivity of the surface energy budget to drifting snow as simulated by MAR in coastal Adelie Land, Antarctica. Cryosphere 15(8): 3595-3614. https://dx.doi.org/10.5194/tc-15-3595-2021","PeerRev":1},{"BRefID":353296,"RR":"Mottram, R.; Hansen, N.; Kittel, C.; Van Wessem, J.M.; Agosta, C.; Amory, C.; Boberg, F.; van de Berg, W.J.; Fettweis, X.; Gossart, A.; van Lipzig, N.P.M.; van Meijgaard, E.; Orr, A.; Phillips, T.; Webster, S.; Simonsen, S.B.; Souverijns, N. (2021). What is the surface mass balance of Antarctica? An intercomparison of regional climate model estimates. Cryosphere 15(8): 3751-3784. https://dx.doi.org/10.5194/tc-15-3751-2021","PeerRev":1},{"BRefID":353188,"RR":"Navari, M.; Margulis, S.A.; Tedesco, M.; Fettweis, X.; van de Wal, R.S.W. (2021). Reanalysis surface mass balance of the Greenland ice sheet along K-transect (2000-2014). Geophys. Res. Lett. 48(17): e2021GL094602. https://dx.doi.org/10.1029/2021GL094602","PeerRev":1},{"BRefID":353275,"RR":"Payne, A.J.; Nowicki, S.; Abe-Ouchi, A.; Agosta, C.; Alexander, P.; Albrecht, T.; Asay-Davis, X.; Aschwanden, A.; Barthel, A.; Bracegirdle, T.J.; Calov, R.; Chambers, C.; Choi, Y.; Cullather, R.; Cuzzone, J.; Dumas, C.; Edwards, T.L.; Felikson, D.; Fettweis, X.; Galton-Fenzi, B.K.; Goelzer, H.; Gladstone, R.; Golledge, N.R.; Gregory, J.M.; Greve, R.; Hattermann, T.; Hoffman, M.J.; Humbert, A.; Huybrechts, P.; Jourdain, N.C.; Kleiner, T.; Kuipers Munneke, P.; Larour, E.; Le Clec'h, S.; Lee, V.; Leguy, G.; Lipscomb, W.H.; Little, C.M.; Lowry, D.P.; Morlighem, M.; Nias, I.; Pattyn, F.; Pelle, T.; Price, S.F.; Quiquet, A.; Reese, R.; Rückamp, M.; Schlegel, N.-J.; Seroussi, H.; Shepherd, A.; Simon, E.; Slater, D.; Smith, R.S.; Straneo, F.; Sun, S.; Tarasov, L.; Trusel, L.D.; Van Breedam, J.; van de Wal, R.; van den Broeke, M.; Winkelmann, R.; Zhao, C.; Zhang, T.; Zwinger, T. (2021). Future sea level change under coupled model intercomparison project phase 5 and phase 6 scenarios from the Greenland and Antarctic ice sheets. Geophys. Res. Lett. 48(16): e2020GL091741. https://dx.doi.org/10.1029/2020GL091741","PeerRev":1},{"BRefID":352969,"RR":"Pohl, B.; Favier, V.; Wille, J.; Udy, D.G.; Vance, T.R.; Pergaud, J.; Dutrievoz, N.; Blanchet, J.; Kittel, C.; Amory, C.; Krinner, G.; Codron, F. (2021). Relationship between weather regimes and atmospheric rivers in East Antarctica. JGR: Atmospheres 126(24): e2021JD035294. https://dx.doi.org/10.1029/2021JD035294","PeerRev":1},{"BRefID":354012,"RR":"Verjans, V.; Leeson, A.A.; McMillan, M.; Stevens, C.M.; van Wessem, J.M.; van de Berg, W.J.; van den Broeke, M.R.; Kittel, C.; Amory, C.; Fettweis, X.; Hansen, N.; Boberg, F.; Mottram, R. (2021). Uncertainty in East Antarctic firn thickness constrained using a model ensemble approach. Geophys. Res. Lett. 48(7): e2020GL092060. https://dx.doi.org/10.1029/2020GL092060","PeerRev":1},{"BRefID":353647,"RR":"Wille, J.D.; Favier, V.; Gorodetskaya, I.V.; Agosta, C.; Kittel, C.; Beeman, J.C.; Jourdain, N.C.; Lenaerts, J.T.M.; Codron, F. (2021). Antarctic atmospheric river climatology and precipitation impacts. JGR: Atmospheres 126(8): e2020JD033788. https://dx.doi.org/10.1029/2020JD033788","PeerRev":1},{"BRefID":322761,"RR":"Donat-Magnin, M.; Jourdain, N.C.; Gallee, H.; Amory, C.; Kittel, C.; Fettweis, X.; Wille, J.D.; Favier, V.; Drira, A.; Agosta, C. (2020). Interannual variability of summer surface mass balance and surface melting in the Amundsen sector, West Antarctica. Cryosphere 14(1): 229-249. https://dx.doi.org/10.5194/tc-14-229-2020","PeerRev":1},{"BRefID":338025,"RR":"Glaude, Q.; Amory, C.; Berger, S.; Derauw, D.; Pattyn, F.; Barbier, C.; Orban, A. (2020). Empirical removal of tides and inverse barometer effect on DInSAR from double DInSAR and a regional climate model. IEEE J. Sel. Top. Appl. Earth Observ. Remote Sens. 13: 4085-4094. https://hdl.handle.net/10.1109/JSTARS.2020.3008497","PeerRev":1},{"BRefID":337819,"RR":"Goelzer, H.; Noël, B.P.Y.; Edwards, T.L.; Fettweis, X.; Gregory, J.M.; Lipscomb, W.H.; van de Wal, R.S.W.; van den Broeke, M.R. (2020). Remapping of Greenland ice sheet surface mass balance anomalies for large ensemble sea-level change projections. Cryosphere 14(6): 1747-1762. https://hdl.handle.net/10.5194/tc-14-1747-2020","PeerRev":1},{"BRefID":337667,"RR":"Goelzer, H.; Nowicki, S.; Payne, A.; Larour, E.; Seroussi, H.; Lipscomb, W.H.; Gregory, J.; Abe-Ouchi, A.; Shepherd, A.; Simon, E.; Agosta, C.; Alexander, P.; Aschwanden, A.; Barthel, A.; Calov, R.; Chambers, C.R.; Choi, Y.; Cuzzone, J.; Dumas, C.; Edwards, T.; Felikson, D.; Fettweis, X.; Golledge, N.R.; Greve, R.; Humbert, A.; Huybrechts, P.; Le Clec'h, S.; Lee, V.; Leguy, G.; Little, C.; Lowry, D.P.; Morlighem, M.; Nias, I.; Quiquet, A.; Rückamp, M.; Schlegel, N.-J.; Slater, D.A.; Smith, R.S.; Straneo, F.; Tarasov, L.; van de Wal, R.; van den Broeke, M. (2020). The future sea-level contribution of the Greenland ice sheet: a multi-model ensemble study of ISMIP6. Cryosphere 14(9): 3071-3096. https://hdl.handle.net/10.5194/tc-14-3071-2020","PeerRev":1},{"BRefID":337755,"RR":"Nowicki, S.; Goelzer, H.; Seroussi, H.; Payne, A.J.; Lipscomb, W.H.; Abe-Ouchi, A.; Agosta, C.; Alexander, P.; Asay-Davis, X.S.; Barthel, A.; Bracegirdle, T.J.; Cullather, R.; Felikson, D.; Fettweis, X.; Gregory, J.M.; Hattermann, T.; Jourdain, N.C.; Munneke, P.K.; Larour, E.; Little, C.M.; Morlighem, M.; Nias, I.; Shepherd, A.; Simon, E.; Slater, D.; Smith, R.S.; Straneo, F.; Trusel, L.D.; van den Broeke, M.R.; van de Wal, R. (2020). Experimental protocol for sea level projections from ISMIP6 stand-alone ice sheet models. Cryosphere 14(7): 2331-2368. https://hdl.handle.net/10.5194/tc-14-2331-2020","PeerRev":1},{"BRefID":337974,"RR":"Ryan, J.C.; Smith, L.C.; Wu, M.; Cooley, S.W.; Miège, C.; Montgomery, L.N.; Koenig, L.S.; Fettweis, X.; Noël, B.P.Y.; van den Broeke, M.R. (2020). Evaluation of CloudSat's cloud-profiling radar for mapping snowfall rates across the Greenland ice sheet. JGR: Atmospheres 125(4): e2019JD031411. https://hdl.handle.net/10.1029/2019JD031411","PeerRev":1},{"BRefID":337940,"RR":"Slater, D.A.; Felikson, D.; Straneo, F.; Goelzer, H.; Little, C.M.; Morlighem, M.; Fettweis, X.; Nowicki, S. (2020). Twenty-first century ocean forcing of the Greenland ice sheet for modelling of sea level contribution. Cryosphere 14(3): 985-1008. https://hdl.handle.net/10.5194/tc-14-985-2020","PeerRev":1},{"BRefID":340293,"RR":"Wyard, C.; Scholzen, C.; Doutreloup, S.; Hallot, E.; Fettweis, X. (2020). Future evolution of the hydroclimatic conditions favouring floods in the south‐east of Belgium by 2100 using a regional climate model. Int. J. Climatol. 41(1): 647-662. https://dx.doi.org/10.1002/joc.6642","PeerRev":1},{"BRefID":311425,"RR":"Agosta, C.; Amory, C.; Kittel, C.; Orsi, A.; Favier, V.; Gallee, H.; van den Broeke, M.R.; Lenaerts, J.T.M.; van Wessem, J.M.; van de Berg, W.J.; Fettweis, X. (2019). Estimation of the Antarctic surface mass balance using the regional climate model MAR (1979-2015) and identification of dominant processes. Cryosphere 13(1): 281-296. https://dx.doi.org/10.5194/tc-13-281-2019","PeerRev":1},{"BRefID":311385,"RR":"Alexander, P.M.; LeGrande, A.N.; Fischer, E.; Tedesco, M.; Fettweis, X.; Kelley, M.; Nowicki, S.M.J.; Schmidt, G.A. (2019). Simulated Greenland Surface Mass Balance in the GISS ModelE2 GCM: role of the ice sheet surface. 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