Surge development in the western sector of the Vavilov Ice Cap, Severnaya Zemlya, 1963–2017

IF 0.7 Q4 GEOSCIENCES, MULTIDISCIPLINARY

Led i Sneg-Ice and Snow Pub Date : 2018-09-26 DOI:10.15356/2076-6734-2018-3-293-306

I. Bushueva, A. Glazovsky, G. Nosenko

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引用次数: 2

Abstract

The glaciers and ice caps in the Arctic are experiencing noticeable changes which are manifested, in particular, in the intensification of their dynamic instability. In this paper we present data on a largescale surge in the Western basin of the Vavilov ice dome on the archipelago Severnaya Zemlya, derived from satellite images and supplemented by airborne RES-2014 and available publications. Analysis of 28 space images of 1963–2017 demonstrated that the surge developed over the whole period. In the fi st decade (1963–1973), the advance was very slow – from 2–5 to 12 m/year. Since the 1980-ies, the ice movement began to accelerate from tens to a hundred of meters per a year in the 2000-ies. The sudden change happened in the year 2012 when the surge front began to move already at speeds of about 0.5 km/year. In 2015, the volume of advanced part reached almost 4 km3. Maximal speed 9.2 km/year was recorded in 2016. From 1963 to 2017, the edge of the glacier advanced by 11.7 km, and its area increased by 134.1 km2 (by 47% relative to the basin area of 1963), that caused spreading of crevasse zone up the glacier. Surface speeds reached a maximum of 25.4 m/day in 2016 and decreased to 7.6 m/day in 2017. The authors suggest that the initial activation of the southern and western edges of the ice dome could be a reaction to the climate signal, possibly occurred several centuries ago. The ice crevassing and cryo-hydrological warming of ice, enhanced by positive feedback, resulted in instability of the glacier and the displacement of the edge of the ice belt containing moraine and frozen to the bed, which transformed into a catastrophic movement. The surge was facilitated by change of bedrock conditions as the ice lobe progressed offshore from permafrost coastal zone to the area of loose marine bottom sediments with low shear strength. The surge seems to be also stimulated by anomalously warm summer of 2012.

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1963-2017年塞维利亚地岛瓦维洛夫冰盖西部地区的急剧发展

北极的冰川和冰帽正在经历明显的变化，特别是表现在其动力不稳定性的加剧。在本文中，我们提供了来自卫星图像并辅以机载RES-2014和现有出版物的关于Severnaya Zemlya群岛Vavilov冰穹西部盆地大规模激增的数据。对1963年至2017年的28张太空图像的分析表明，这一激增是在整个时期发生的。在第一个十年(1963-1973)，进展非常缓慢，从2-5米/年到12米/年。自20世纪80年代以来，冰的移动开始加速，从每年几十米到2000年代的100米。这种突然的变化发生在2012年，当时浪涌锋已经开始以每年约0.5公里的速度移动。2015年，先进部分的体积接近4立方千米。2016年创下的最高速度为9.2公里/年。1963 - 2017年，冰川边缘推进了11.7 km，冰川面积增加了134.1 km2(与1963年的流域面积相比增加了47%)，导致冰川裂缝带向上游扩展。2016年，地面速度达到25.4米/天的最大值，2017年降至7.6米/天。作者认为，冰穹南部和西部边缘的最初激活可能是对气候信号的反应，可能发生在几个世纪前。冰裂和冰的低温-水文变暖在正反馈的作用下增强，导致冰川的不稳定和冰碛冰带边缘的位移，并被冻结到床上，从而转化为灾难性的运动。随着冰瓣从永久冻土带向较低剪切强度的海底松散沉积物区推进，基岩条件的变化促进了浪涌的发生。这种激增似乎也受到2012年异常温暖夏季的刺激。

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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来源期刊

Led i Sneg-Ice and Snow GEOSCIENCES, MULTIDISCIPLINARY-

CiteScore

1.50

自引率

42.90%

发文量

审稿时长

8 weeks

期刊介绍： The journal was established with the aim of publishing new research results of the Earth cryosphere. Results of works in physics, mechanics, geophysics, and geochemistry of snow and ice are published here together with geographical aspects of the snow-ice phenomena occurrence in their interaction with other components of the environment. The challenge was to discuss the latest results of investigations carried out on Russia’s territory and works performed by Russian investigators together with foreign colleagues. Editorial board works in collaboration with Glaciological Association that is professional community of specialists in glaciology from all republics of the Former Soviet Union which are now new independent states. The journal serves as a platform for the presentation and discussion of new discoveries and results which help to elucidate the state of the Earth’s cryosphere and the characteristics of the evolution of the snow-ice processes and phenomena under the current conditions of rapid climate change.