Widespread increase in discharge from west Antarctic Peninsula glaciers since 2018

The Cryosphere Pub Date : 2024-07-19 DOI:10.5194/tc-18-3237-2024

B. Davison, Anna E. Hogg, Carlos Moffat, Michael P. Meredith, Benjamin J. Wallis

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Abstract

Abstract. Many glaciers on the Antarctic Peninsula have retreated and accelerated in recent decades. Here we show that there has been a widespread, quasi-synchronous, and sustained increase in grounding line discharge from glaciers on the west coast of the Antarctic Peninsula since 2018. Overall, the west Antarctic Peninsula discharge trends increased by over a factor of 3, from 50 Mt yr−2 during 2017 to 2020 up to 160 Mt yr−2 in the years following, leading to a 7.4 % increase in grounding line discharge since 2017. The acceleration in discharge was concentrated at glaciers connected to deep, cross-shelf troughs hosting warm-ocean waters, and the acceleration occurred during a period of anomalously high subsurface water temperatures on the continental shelf. Given that many of the affected glaciers have retreated over the past several decades in response to ocean warming, thereby highlighting their sensitivity to ocean forcing, we argue that the recent period of anomalously warm water was likely a key driver of the observed acceleration. However, the acceleration also occurred during a time of anomalously high atmospheric temperatures and glacier surface runoff, which could have contributed to speed-up by directly increasing basal water pressure and, by invigorating near-glacier ocean circulation, increasing submarine melt rates. The spatial pattern of glacier acceleration therefore provides an indication of glaciers that are exposed to warm-ocean water at depth and/or have active surface-to-bed hydrological connections; however, many stages in the chain of events leading to glacier acceleration, and how that response is affected by glacier-specific factors, remain insufficiently understood. Both atmospheric and ocean temperatures in this region and its surroundings are likely to increase further in the coming decades; therefore, there is a pressing need to improve our understanding of recent changes in Antarctic Peninsula glacier dynamics in response atmospheric and oceanic changes in order to improve projections of their behaviour over the coming century.

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2018 年以来南极半岛西部冰川排水量大范围增加

摘要近几十年来，南极半岛上的许多冰川都出现了后退和加速现象。我们在此表明，自2018年以来，南极半岛西海岸冰川的接地线排泄量出现了广泛、准同步和持续的增加。总体而言，南极半岛西部的排泄量趋势增加了 3 倍多，从 2017 年至 2020 年期间的 5 千万吨/年-2 增加到随后几年的 1.6 亿吨/年-2，导致自 2017 年以来接地线排泄量增加了 7.4%。排泄量的加速主要集中在与承载暖洋水的跨大陆架深槽相连的冰川，而且加速发生在大陆架表层下水温异常高的时期。鉴于许多受影响的冰川在过去几十年中因海洋变暖而后退，从而凸显了它们对海洋胁迫的敏感性，我们认为近期的异常暖水期很可能是观测到的加速现象的主要驱动因素。然而，冰川加速也发生在大气温度和冰川表面径流异常高的时期，大气温度和冰川表面径流可能会直接增加基底水压，并通过激活冰川附近的海洋环流，提高海底融化率，从而促进冰川加速。因此，冰川加速的空间模式表明，冰川深处暴露在温暖的海水中，和/或冰川表面与冰床之间有活跃的水文联系；然而，人们对导致冰川加速的一系列事件中的许多阶段，以及冰川特有的因素如何影响这种反应，仍然了解不够。该地区及其周边地区的大气和海洋温度在未来几十年可能会进一步升高；因此，我们迫切需要更好地了解南极半岛冰川动力学在应对大气和海洋变化方面的最新变化，以便更好地预测冰川在未来一个世纪的行为。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Cryosphere

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