Seroussi, Hélène, Pelle, Tyler, Lipscomb, William H., Abe‐Ouchi, Ayako, Albrecht, Torsten, Alvarez‐Solas, Jorge, Asay‐Davis, Xylar, Barre, Jean‐Baptiste, Berends, Constantijn J., Bernales, Jorge, Blasco, Javier, Caillet, Justine, Chandler, David M., Coulon, Violaine, Cullather, Richard, Dumas, Christophe, Galton‐Fenzi, Benjamin K., Garbe, Julius, Gillet‐Chaulet, Fabien, and Gladstone, Rupert
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. Plain Language Summary: Numerical models simulating the evolution of the Antarctic Ice Sheet have mostly focused on the twenty‐first century. How the ice sheet will evolve after 2100 remains highly uncertain, as several instability mechanisms could develop and destabilize vast regions of Antarctica. We investigate here the behavior of the Antarctic Ice Sheet until 2300 using an ensemble of 16 different ice flow models. The results show that the Antarctic contribution to sea‐level rise remains limited until 2100 but increases rapidly afterward. The ice retreats in most basins of the West Antarctic Ice Sheet, and some numerical experiments suggest a near‐complete collapse of this region by 2300. The time when these glaciers start retreating varies depending on the choice of ice flow model, but the speed at which they retreat is consistent among the models once the retreat begins. On a multi‐century timescale, the choice of ice sheet model remains a leading source of uncertainties. Key Points: Antarctic Ice Sheet mass loss and associated uncertainty increase sharply after 2100Ice streams feeding the Ross and Ronne ice shelves experience considerable and consistent grounding line retreat for all ice sheet modelsOn multi‐centennial timescales, uncertainty in mass loss remains dominated by the choice of ice flow model, followed by the climate forcing [ABSTRACT FROM AUTHOR]