English

Evolution of the Antarctic Ice Sheet Over the Next Three Centuries From an ISMIP6 Model Ensemble

Earth's Future ()

https://doi.org/10.1029/2024ef004561

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under lisensen CC BY

Forfattere (53)
  1. Hélène Seroussi
  2. Tyler Pelle
  3. William H. Lipscomb
  4. Ayako Abe-Ouchi
  5. Torsten Albrecht
  6. Jorge Alvarez-Solas
  7. Xylar Asay-Davis
  8. Jean-Baptiste Barre
  9. Constantijn J. Berends
  10. Jorge Bernales
  11. Javier Blasco
  12. Justine Caillet
  13. David Matthew Chandler
  14. Violaine Coulon
  15. Richard Cullather
  16. Christophe Dumas
  17. Benjamin K. Galton-Fenzi
  18. Julius Garbe
  19. Fabien Gillet-Chaulet
  20. Rupert Gladstone
  21. Heiko Goelzer
  22. Nicholas Golledge
  23. Ralf Greve
  24. G. Hilmar Gudmundsson
  25. Holly Kyeore Han
  26. Trevor R. Hillebrand
  27. Matthew J. Hoffman
  28. Philippe Huybrechts
  29. Nicolas C. Jourdain
  30. Ann Kristin Klose
  31. Petra Margaretha Langebroek
  32. Gunter R. Leguy
  33. Daniel P. Lowry
  34. Pierre Mathiot
  35. Marisa Montoya
  36. Mathieu Morlighem
  37. Sophie Nowicki
  38. Frank Pattyn
  39. Anthony J. Payne
  40. Aurélien Quiquet
  41. Ronja Reese
  42. Alexander Robinson
  43. Leopekka Saraste
  44. Erika G. Simon
  45. Sainan Sun
  46. Jake P. Twarog
  47. Luke D. Trusel
  48. Benoit Urruty
  49. Jonas Van Breedam
  50. Roderik S.W. van de Wal
  51. Yu Wang
  52. Chen Zhao
  53. Thomas Zwinger

Abstract

The Ice Sheet Model Intercomparison Project for CMIP6 (ISMIP6) is the primary effort of CMIP6 (Coupled Model Intercomparison Project–Phase 6) focusing on ice sheets, designed to provide an ensemble of process-based projections of the ice-sheet contribution to sea-level rise over the twenty-first century. However, the behavior of the Antarctic Ice Sheet beyond 2100 remains largely unknown: several instability mechanisms can develop on longer time scales, potentially destabilizing large parts of Antarctica. Projections of Antarctic Ice Sheet evolution until 2300 are presented here, using an ensemble of 16 ice-flow models and forcing from global climate models. Under high-emission scenarios, the Antarctic sea-level contribution is limited to less than 30 cm sea-level equivalent (SLE) by 2100, but increases rapidly thereafter to reach up to 4.4 m SLE by 2300. Simulations including ice-shelf collapse lead to an additional 1.1 m SLE on average by 2300, and can reach 6.9 m SLE. Widespread retreat is observed on that timescale in most West Antarctic basins, leading to a collapse of large sectors of West Antarctica by 2300 in 30%–40% of the ensemble. While the onset date of retreat varies among ice models, the rate of upstream propagation is highly consistent once retreat begins. Calculations of sea-level contribution including water density corrections lead to an additional ∼10% sea level and up to 50% for contributions accounting for bedrock uplift in response to ice loading. Overall, these results highlight large sea-level contributions from Antarctica and suggest that the choice of ice sheet model remains the leading source of uncertainty in multi-century projections.

Prosjekter
  • iC3: Centre for Ice, Cryosphere, Carbon and Climate
  • Fra klimatiske drivere til iskappen over Antarktis: bedre prognoser for havnivåstigning{"id":"01k894aagv93y00s7tjz0wadjr","abbr":"CLIM2Ant","created":"2025-10-23T18:11:58.011Z","created_by":"che@akvaplan.niva.no","updated":"2025-10-25T15:07:05.408Z","updated_by":"che@akvaplan.niva.no","title":{"en":"From Climatic Drivers to Antarctic Ice Sheet Response: Improving Accuracy in Sea Level Rise Projections","no":"Fra klimatiske drivere til iskappen over Antarktis: bedre prognoser for havnivåstigning"},"summary":{"en":"The Antarctic Ice Sheet (AIS) stores a large amount of freshwater. If melted completely, it would contribute 58 m to global mean sea level rise. According to IPCC AR6, a rise of up to 5 m by 2150 cannot be ruled out under a high-emission scenario due to the large uncertainty related to AIS processes. Such a strong increase in sea level would becatastrophic for many low-lying regions worldwide, but how likely is it?\n\nThe AIS gains mass mainly through snow accumulation and loses mass through iceberg calving and ocean-inducedbasal melting of its floating parts. Future projections of AIS mass balance are based on ice sheet model simulationsforced by climate model outputs. Climate models can properly project large-scale climate changes but struggle torepresent small-scale coastal processes that bring heat to the ice sheet margins. This leads to poor representation ofbasal melting and thus substantial uncertainties in projections of Antarctica's contribution to sea level rise. Climatemodels also suggest compensating mass change under climate warming in Dronning Maud Land: increased basalmelting and more snowfall.This project brings together glaciology and oceanography, sophisticated numerical modelling and statistical analysistechniques to address these two key uncertainties of sea level rise projections:1) Our combined approach of ocean model downscaling and statistical emulation enables us to assess future ocean-induced AIS mass loss more accurately and thus reduce uncertainties in its contribution to sea level rise.2) Our regional fine-resolution coupled ice sheet-ocean model enables us to provide improved projections for icemass balance and ice sheet movement in the Norwegian administrated Dronning Maud Land sector of Antarctica.Our project outcomes will directly contribute to future assessments of ice sheet sea-level contributions and addresstwo of the goals of the EU Decade for Ocean Research: a predicted ocean and an accessible ocean.","no":"Havnivåstigning er en av de største truslene mot menneskeheten som følge av klimaendringene. Endringene i havnivå styres hovedsakelig av smeltingen av isbreer og iskapper, samt utvidelse av havvann når det varmes opp. Det er per i dag forventet at havnivået vil stige med 60 cm innen dette århundret.\n\nDersom utslippene av klimagasser fortsetter å være høye kan smeltingen av iskappen over Antarktis (kalt \"Antarctic Ice Sheet\" - AIS) bety en havnivåstigning på 5 meter innen 2150. En slik stigning i havnivået vil ha katastrofale konsekvenser for lavtliggende områder i hele verden. Men hvor sannsynlig er det? Den Antarktiske iskappen består av 90% av all is på jorden. Hvis alt dette skulle smelte så ville det bety en havnivåstigning på 58 meter. \n\nÅ forutse smeltingen av AIS er derfor av kritisk betydning for myndigheter og beslutningstagere for å avgjøre hvilke tiltak og strategier som skal velges for å redusere utslipp av klimagasser og å forebygge konsekvenser av den globale oppvarmingen. AIS vokser i hovedsak ved akkumulering av snø og minsker gjennom smelteprosesser der isbremmen er i kontakt med Sørishavet.\n\nPrediksjoner av massebalansen til AIS er basert på numeriske modeller. Men det er knyttet usikkerhet til hvor mye smeltingen av isen i Antarktis vil bidra til havnivåendringer i fremtiden. Ved å kombinere fagområdene glasiologi og oseanografi med numeriske modellering og statistikk søker dette prosjektet (CLIM2Ant) å forbedre vår evne til å forutse hvordan isen i Antarktis vil bidra til havnivåendringene. Prosjektets resultater vil bidra direkte til fremtidige vurderinger av hvilken påvirkning AIS vil ha på havnivået."},"modified":"2025-10-25T15:07:04.960Z","start":"2024-01-01","end":"2027-12-31","rcn":343397,"cristin":2730024,"fhf":0,"mynewsdesk":0,"published":"2025-10-23T18:11:58.011Z","akvaplanists":["qin"],"lang":"no"}

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