Accelerated glacier mass loss in the mid-latitude Eurasia from 2019 to 2022 revealed by ICESat-2

IF 6.4 1区 地球科学 Q1 ENVIRONMENTAL SCIENCES Advances in Climate Change Research Pub Date : 2024-10-01 DOI:10.1016/j.accre.2024.09.008
Gen-Yu Wang , Chang-Qing Ke , Yu-Bin Fan , Xiao-Yi Shen , Yu Cai , Vahid Nourani
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Abstract

The dynamics of glaciers serve as one of the most important indicators of climate change. Whilst current research has primarily concentrated on long-term interannual glacier mass balance and its response to climate change, glaciers may respond more rapidly to climate change, highlighting the urgent need for intra-annual mass balance estimations. Investigating seasonal or short-term variations in glacier mass balance not only enhances our understanding of the interactions between glaciers and the climate system but also provides crucial data for water resource management and ecological protection. The ICESat-2 and NASADEM datasets were used to estimate the inter- and intra-annual glacier mass balance changes in the mid-latitude Eurasia from 2019 to 2022. Additionally, the response of glacier mass balance to regional air temperature and precipitation values was analysed using ERA5-Land data and multiple regression analysis, respectively. From 2019 to 2022, glacier mass loss in mid-latitude Eurasia reached −45.02 ± 34.21 Gt per year, contributing to a global sea-level rise of 0.12 ± 0.09 mm per year. The glacier melt rate in the study area from 2019 to 2022 was 2.33 times higher than that from 2000 to 2019. With the exception of the Western Kunlun region, which experienced a weak accumulation rate of 0.04 ± 0.35 m w.e. per year, all other areas experienced ablation states. Seasonal mass balance responds differently to temperature and precipitation variations across seasons: higher temperatures in different seasons lead to more negative mass balances, while increased winter and spring precipitation can slow down glacier melt. Air temperature dominates the glacier mass balance changes in the study area. The intense heat in 2022 raised average glacier temperatures by 1.04 °C compared to 2019–2021, resulting in a more negative mass balance and an increased ice loss of −0.34 ± 1.01 m w.e. per year (−35.07 ± 103.22 Gt per year). This analysis indicates that glacier mass balance is highly sensitive to climate change, even on a seasonal scale. Moreover, the high precision and spatiotemporal resolution ICESat-2 data can facilitate the investigation of large-scale glacier mass balance on short time scales.
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ICESat-2 号卫星揭示的 2019 年至 2022 年欧亚大陆中纬度地区冰川加速消融的情况
冰川动力学是气候变化最重要的指标之一。虽然目前的研究主要集中在长期的年际冰川质量平衡及其对气候变化的反应上,但冰川可能会对气候变化做出更迅速的反应,这就凸显了对年内质量平衡估算的迫切需要。调查冰川质量平衡的季节或短期变化不仅能加深我们对冰川与气候系统之间相互作用的理解,还能为水资源管理和生态保护提供重要数据。利用ICESat-2和NASADEM数据集估算了2019年至2022年欧亚大陆中纬度地区年际和年内的冰川质量平衡变化。此外,利用ERA5-Land数据和多元回归分析分别分析了冰川质量平衡对区域气温和降水值的响应。从2019年到2022年,欧亚大陆中纬度地区的冰川质量损失达到每年-45.02 ± 34.21 Gt,导致全球海平面每年上升0.12 ± 0.09 mm。研究地区 2019 年至 2022 年的冰川融化率是 2000 年至 2019 年的 2.33 倍。除了西昆仑地区的积聚率较弱,为每年 0.04 ± 0.35 米(湿重)外,其他地区都出现了消融状态。季节性质量平衡对不同季节的气温和降水量变化有不同的反应:不同季节较高的气温会导致更多的负质量平衡,而冬季和春季降水量的增加会减缓冰川融化。气温主导着研究区域的冰川质量平衡变化。与 2019-2021 年相比,2022 年的高温使冰川平均温度升高了 1.04 °C,导致冰川质量平衡出现更多负值,冰川损失增加了 -0.34 ± 1.01 m w.e.(-35.07 ± 103.22 Gt/年)。这一分析表明,冰川质量平衡对气候变化高度敏感,即使在季节尺度上也是如此。此外,ICESat-2 数据的高精度和时空分辨率有助于研究短时间尺度上的大尺度冰川质量平衡。
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来源期刊
Advances in Climate Change Research
Advances in Climate Change Research Earth and Planetary Sciences-Atmospheric Science
CiteScore
9.80
自引率
4.10%
发文量
424
审稿时长
107 days
期刊介绍: Advances in Climate Change Research publishes scientific research and analyses on climate change and the interactions of climate change with society. This journal encompasses basic science and economic, social, and policy research, including studies on mitigation and adaptation to climate change. Advances in Climate Change Research attempts to promote research in climate change and provide an impetus for the application of research achievements in numerous aspects, such as socioeconomic sustainable development, responses to the adaptation and mitigation of climate change, diplomatic negotiations of climate and environment policies, and the protection and exploitation of natural resources.
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