48 citations as recorded by crossref.

1. Estimating Greenland tidewater glacier retreat driven by submarine melting D. Slater et al.
2. Quantification of Surface Forcing Requirements for a Greenland Ice Sheet Model Using Uncertainty Analyses N. Schlegel & E. Larour
3. Spatially Heterogeneous Effects of Atmospheric Circulation on Greenland Ice Sheet Melting H. Wang et al.
4. Eemian Greenland ice sheet simulated with a higher-order model shows strong sensitivity to surface mass balance forcing A. Plach et al.
5. Diverging future surface mass balance between the Antarctic ice shelves and grounded ice sheet C. Kittel et al.
6. Atmospheric drivers of melt-related ice speed-up events on the Russell Glacier in southwest Greenland T. Schmid et al.
7. A 21st Century Warming Threshold for Sustained Greenland Ice Sheet Mass Loss B. Noël et al.
8. Remapping of Greenland ice sheet surface mass balance anomalies for large ensemble sea-level change projections H. Goelzer et al.
9. Seasonal evolution of basal environment conditions of Russell sector, West Greenland, inverted from satellite observation of surface flow A. Derkacheva et al.
10. Greenland surface air temperature changes from 1981 to 2019 and implications for ice‐sheet melt and mass‐balance change E. Hanna et al.
11. Early Holocene Laurentide Ice Sheet Retreat Influenced Summer Atmospheric Circulation in Baffin Bay E. Thomas et al.
12. Contribution of surface and cloud radiative feedbacks to Greenland Ice Sheet meltwater production during 2002–2023 J. Ryan
13. Large and irreversible future decline of the Greenland ice sheet J. Gregory et al.
14. Brief communication: Reduction in the future Greenland ice sheet surface melt with the help of solar geoengineering X. Fettweis et al.
15. Modeling the Greenland Ice Sheet's Committed Contribution to Sea Level During the 21st Century I. Nias et al.
16. Effects of extreme melt events on ice flow and sea level rise of the Greenland Ice Sheet J. Beckmann & R. Winkelmann
17. Long‐term projections of sea‐level rise from ice sheets N. Golledge
18. Limited global effect of climate-Greenland ice sheet coupling in NorESM2 under a high-emission scenario K. Haubner et al.
19. Greater Greenland Ice Sheet contribution to global sea level rise in CMIP6 S. Hofer et al.
20. ISMIP6 Antarctica: a multi-model ensemble of the Antarctic ice sheet evolution over the 21st century H. Seroussi et al.
21. The role of an interactive Greenland ice sheet in the coupled climate-ice sheet model EC-Earth-PISM M. Madsen et al.
22. The albedo loss from the melting of the Greenland ice sheet and the social cost of carbon S. Gschnaller
23. Shortwave cloud warming effect observed over highly reflective Greenland H. Zhang et al.
24. A rapidly converging initialisation method to simulate the present-day Greenland ice sheet using the GRISLI ice sheet model (version 1.3) S. Le clec'h et al.
25. Uncertainties in projected surface mass balance over the polar ice sheets from dynamically downscaled EC-Earth models F. Boberg et al.
26. Short- and long-term variability of the Antarctic and Greenland ice sheets E. Hanna et al.
27. Retrieval of atmospheric water vapor and temperature profiles over Antarctica from satellite microwave observations using an iterative approach Z. Zhang et al.
28. The future sea-level contribution of the Greenland ice sheet: a multi-model ensemble study of ISMIP6 H. Goelzer et al.
29. Analysis of the surface mass balance for deglacial climate simulations M. Kapsch et al.
30. Positive feedbacks drive the Greenland ice sheet evolution in millennial-length MAR–GISM simulations under a high-end warming scenario C. Paice et al.
31. The GRISLI-LSCE contribution to the Ice Sheet Model Intercomparison Project for phase 6 of the Coupled Model Intercomparison Project (ISMIP6) – Part 2: Projections of the Antarctic ice sheet evolution by the end of the 21st century A. Quiquet & C. Dumas
32. Exploring the Greenland Ice Sheet’s response to future atmospheric warming-threshold scenarios over 200 years A. Delhasse et al.
33. The GRISLI-LSCE contribution to the Ice Sheet Model Intercomparison Project for phase 6 of the Coupled Model Intercomparison Project (ISMIP6) – Part 1: Projections of the Greenland ice sheet evolution by the end of the 21st century A. Quiquet & C. Dumas
34. GrSMBMIP: intercomparison of the modelled 1980–2012 surface mass balance over the Greenland Ice Sheet X. Fettweis et al.
35. Air Pollution and Its Association with the Greenland Ice Sheet Melt K. Vikrant et al.
36. Bridging the spatiotemporal ice sheet mass change data gap between GRACE and GRACE-FO in Greenland using machine learning method Z. Shi et al.
37. Coupling MAR (Modèle Atmosphérique Régional) with PISM (Parallel Ice Sheet Model) mitigates the positive melt–elevation feedback A. Delhasse et al.
38. Present‐Day Greenland Ice Sheet Climate and Surface Mass Balance in CESM2 L. van Kampenhout et al.
39. Greenland climate simulations show high Eemian surface melt which could explain reduced total air content in ice cores A. Plach et al.
40. A High‐End Estimate of Sea Level Rise for Practitioners R. van de Wal et al.
41. Distribution and Evolution of Supraglacial Lakes in Greenland during the 2016–2018 Melt Seasons J. Hu et al.
42. Improving modelled albedo over the Greenland ice sheet through parameter optimisation and MODIS snow albedo retrievals N. Raoult et al.
43. Projecting Antarctica's contribution to future sea level rise from basal ice shelf melt using linear response functions of 16 ice sheet models (LARMIP-2) A. Levermann et al.
44. Impact of the melt–albedo feedback on the future evolution of the Greenland Ice Sheet with PISM-dEBM-simple M. Zeitz et al.
45. Role of Snowfall Versus Air Temperatures for Greenland Ice Sheet Melt‐Albedo Feedbacks J. Ryan et al.
46. How many modes are needed to predict climate bifurcations? Lessons from an experiment B. Dubrulle et al.
47. Investigating the multi-millennial evolution and stability of the Greenland ice sheet using remapped surface mass balance forcing C. Rahlves et al.
48. Greenland Ice Sheet Contribution to 21st Century Sea Level Rise as Simulated by the Coupled CESM2.1‐CISM2.1 L. Muntjewerf et al.