Impact of an acceleration of ice sheet melting on monsoon systems

A. Chemison, D. Defrance, G. Ramstein, C. Caminade
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引用次数: 1

Abstract

Abstract. The study of past climates has demonstrated the occurrence of Heinrich events during which major ice discharges occurred at the polar ice sheet, leading to significant additional sea level rise. Heinrich events strongly influenced the oceanic circulation and global climate. However, standard climate change scenarios (Representative Concentration Pathways or RCPs) do not consider such potential rapid ice sheet collapse; RCPs only consider the dynamic evolution of greenhouse gas emissions. We carried out water-hosing simulations using the Institute Pierre Simon Laplace global Climate Model (IPSL-CM5A) to simulate a rapid melting of the Greenland and Antarctic ice sheets, equivalent to +1 and +3 m additional sea level rise (SLR). Freshwater inputs were added to the standard RCP8.5 emission scenario over the 21st century. The contribution to the SLR from Greenland or from Antarctic ice sheets has differentiated impacts. The freshwater input in the Antarctic is diluted by the circumpolar current, and its global impact is moderate. Conversely, a rapid melting of the ice sheet in the North Atlantic slows down the Atlantic Meridional Overturning Circulation. This slowdown leads to changes in winds, inter-hemispheric temperature and pressure gradients, resulting in a southward shift of the tropical rain belt over the Atlantic and eastern Pacific region. The American and African monsoons are strongly affected and shift to the south. Changes in the North American monsoon occur later, while changes in the South American monsoon start earlier. The North African monsoon is drier during boreal summer, while the southern African monsoon intensifies during austral summer. Simulated changes were not significant for the Asian and Australian monsoons.
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冰盖融化加速对季风系统的影响
摘要对过去气候的研究表明,海因里希事件的发生,在此期间,极地冰盖发生了主要的冰排放,导致海平面显著上升。海因里希事件强烈影响了海洋环流和全球气候。然而,标准的气候变化情景(代表性集中路径或RCP)没有考虑到这种潜在的快速冰盖崩塌;RCP只考虑温室气体排放的动态演变。我们使用皮埃尔·西蒙·拉普拉斯研究所全球气候模型(IPSL-CM5A)进行了喷水模拟,以模拟格陵兰岛和南极冰盖的快速融化,相当于+1和+3 m额外海平面上升(SLR)。淡水输入被添加到21世纪标准RCP8.5排放情景中。格陵兰岛或南极冰盖对SLR的贡献具有不同的影响。南极的淡水输入被环极流稀释,其全球影响是中等的。相反,北大西洋冰盖的快速融化减缓了大西洋经向翻转环流。这种减缓导致风、半球间温度和压力梯度的变化,导致大西洋和东太平洋地区热带雨带南移。美国和非洲的季风受到强烈影响,并向南转移。北美季风的变化发生得较晚,而南美季风的变化开始得更早。北非季风在北方夏季较为干燥,而南部非洲季风在南方夏季增强。模拟的变化对亚洲和澳大利亚的季风来说并不显著。
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