Spatiotemporal change analysis for snowmelt over the Antarctic ice shelves using scatterometers

A. J. Luis, Mahfooz Alam, S. Jawak
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Abstract

Using Scatterometer-based backscatter data, the spatial and temporal melt dynamics of Antarctic ice shelves were tracked from 2000 to 2018. We constructed melt onset and duration maps for the whole Antarctic ice shelves using a pixel-based, adaptive threshold approach based on backscatter during the transition period between winter and summer. We explore the climatic influences on the spatial extent and timing of snowmelt using meteorological data from automatic weather stations and investigate the climatic controls on the spatial extent and timing of snowmelt. Melt extent usually starts in the latter week of November, peaks in the end of December/January, and vanishes in the first/second week of February on most ice shelves. On the Antarctic Peninsula (AP), the average melt was 70 days, with the melt onset on 20 November for almost 50% of the region. In comparison to the AP, the Eastern Antarctic experienced less melt, with melt lasting 40–50 days. For the Larsen-C, Shackleton, Amery, and Fimbul ice shelf, there was a substantial link between melt area and air temperature. A significant correlation is found between increased temperature advection and high melt area for the Amery, Shackleton, and Larsen-C ice shelves. The time series of total melt area showed a decreasing trend of −196 km2/yr which was statistical significant at 97% interval. The teleconnections discovered between melt area and the combined anomalies of Southern Annular Mode and Southern Oscillation Index point to the high southern latitudes being coupled to the global climate system. The most persistent and intensive melt occurred on the AP, West Ice Shelf, Shackleton Ice Shelf, and Amery Ice Shelf, which should be actively monitored for future stability.
利用散射计分析南极冰架融雪的时空变化
利用基于散射计的后向散射数据,追踪了2000 - 2018年南极冰架的时空融化动态。利用基于后向散射的基于像素的自适应阈值方法,我们构建了整个南极冰架在冬夏过渡时期的融化开始和持续时间图。利用自动气象站资料,探讨了气候对融雪空间范围和时间的影响,探讨了气候对融雪空间范围和时间的控制。在大多数冰架上,融化程度通常在11月的最后一周开始,在12月底/ 1月达到顶峰,在2月的第一周/第二周消失。在南极半岛(AP),平均融化时间为70天,几乎50%的地区在11月20日开始融化。与AP相比,南极东部的融化较少,融化持续了40-50天。对于拉森- c冰架、沙克尔顿冰架、艾默里冰架和芬布尔冰架来说,融化面积和气温之间存在着实质性的联系。温度平流的增加与Amery、Shackleton和Larsen-C冰架的高融化面积之间存在显著的相关性。总融化面积在时间序列上呈- 196 km2/yr的递减趋势,在97%的间隔上具有统计学显著性。融冰面积与南环模和南方涛动指数的联合异常之间的遥相关表明,南纬高纬度与全球气候系统耦合。最持久和最强烈的融化发生在AP、西冰架、沙克尔顿冰架和Amery冰架,应该积极监测未来的稳定性。
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