R. Greve, C. Chambers, T. Obase, F. Saito, W. Chan, A. Abe‐Ouchi
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引用次数: 0
摘要
作为耦合模式比对项目第6阶段(CMIP6)的一部分,CMIP6冰盖模式比对项目(ISMIP6)旨在评估地球冰盖可能对海平面上升的贡献。在此,我们基于原始的ISMIP6至2100年的强迫,结合MIROC4m至2300年气候模式模拟的气候指数,构建了南极洲至2300年的气候强迫集合。然后,我们利用这些强迫用SICOPOLIS模式对南极冰盖进行模拟。在不减弱的升温路径RCP8.5/SSP5-8.5中,冰盖遭受了严重的质量损失,14个实验的平均值为~ 1.5 m SLE(海平面当量),最敏感的实验为~ 3.3 m SLE。这种损失大部分来自南极洲西部。对于RCP2.6/SSP1-2.6的减排路径,损失限制在3个实验的平均值~ 0.16 m SLE。这一平均值比之前的研究(Chambers等人,2022,doi:10.1017/ joj .2021.124)中发现的平均值大约大两倍,该研究假设21世纪末的气候在2100年之后持续,证明了2100年后气候趋势对22世纪和23世纪南极质量变化的重要性。
Future projections for the Antarctic ice sheet until the year 2300 with a climate-index method
As part of the Coupled Model Intercomparison Project Phase 6 (CMIP6), the Ice Sheet Model Intercomparison Project for CMIP6 (ISMIP6) was devised to assess the likely sea-level-rise contribution from the Earth's ice sheets. Here, we construct an ensemble of climate forcings for Antarctica until the year 2300 based on original ISMIP6 forcings until 2100, combined with climate indices from simulations with the MIROC4m climate model until 2300. We then use these forcings to run simulations for the Antarctic ice sheet with the SICOPOLIS model. For the unabated warming pathway RCP8.5/SSP5-8.5, the ice sheet suffers a severe mass loss, amounting to ~ 1.5 m SLE (sea-level equivalent) for the fourteen-experiment mean, and ~ 3.3 m SLE for the most sensitive experiment. Most of this loss originates from West Antarctica. For the reduced emissions pathway RCP2.6/SSP1-2.6, the loss is limited to a three-experiment mean of ~ 0.16 m SLE. The means are approximately two times larger than what was found in a previous study (Chambers and others, 2022, doi:10.1017/jog.2021.124) that assumed a sustained late-21st-century climate beyond 2100, demonstrating the importance of post-2100 climate trends on Antarctic mass changes in the 22nd and 23rd centuries.
期刊介绍:
Journal of Glaciology publishes original scientific articles and letters in any aspect of glaciology- the study of ice. Studies of natural, artificial, and extraterrestrial ice and snow, as well as interactions between ice, snow and the atmospheric, oceanic and subglacial environment are all eligible. They may be based on field work, remote sensing, laboratory investigations, theoretical analysis or numerical modelling, or may report on newly developed glaciological instruments. Subjects covered recently in the Journal have included palaeoclimatology and the chemistry of the atmosphere as revealed in ice cores; theoretical and applied physics and chemistry of ice; the dynamics of glaciers and ice sheets, and changes in their extent and mass under climatic forcing; glacier energy balances at all scales; glacial landforms, and glaciers as geomorphic agents; snow science in all its aspects; ice as a host for surface and subglacial ecosystems; sea ice, icebergs and lake ice; and avalanche dynamics and other glacial hazards to human activity. Studies of permafrost and of ice in the Earth’s atmosphere are also within the domain of the Journal, as are interdisciplinary applications to engineering, biological, and social sciences, and studies in the history of glaciology.