The iceberg drift study near Severnaya Zemlya in the spring of 2018 by remote sensing data

IF 0.7 Q4 GEOSCIENCES, MULTIDISCIPLINARY

Led i Sneg-Ice and Snow Pub Date : 2019-09-21 DOI:10.15356/2076-6734-2019-3-411

I. Bychkova, V. Smirnov

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引用次数: 0

Abstract

The movement of icebergs in the Laptev Sea off the coast of the Severnaya Zemlya archipelago in spring of 2018 was analyzed using satellite observations in visible spectral band. As is shown in the article the data of radiometers installed on the Landsat-8 and Sentinel-2 satellites allow monitoring of iceberg drifting in spring period in the above Arctic region. Thus, in March–April 2018, the total amount of icebergs detected near the archipelago was 4917. 4161 icebergs were in the landfast ice, 722 ones were drifting with the ice fields, and the other 32 were aground in ice fields. The average length of the icebergs was equal to 88 m; the largest of the recognized icebergs was located in the landfast ice near the ice shelf of the Matusevich fjord and it was 1240 m in length. The maximum speed of drift of the icebergs, as determined by the satellite data, was equal to 29.5 km/day. This was estimated for the situation when the speed of the near-water (surface) wind reached 20 m/s and larger. The purpose of the work was to study drifting of icebergs in order to define more exactly dynamics of the iceberg movement in this poorly known area of the Arctic. It is found that in a case of the consolidated ice cover the drift speed of ice fields with the icebergs involved depends on the driving wind force and direction. According to mean speeds of movement all icebergs were separated into three groups: the icebergs of the coastal zone with velocities smaller 1 km/day; the icebergs of the transition zone at speeds of 1.3 to 1.6 km/day; and the icebergs of the transit zone with speeds larger 2 km/day. The characteristics of the iceberg drifts obtained on the basis of daily satellite monitoring can be used in regional iceberg drift models to ensure safe economic activity on the Arctic shelf. Also, they can find application in engineering calculations in the design of infrastructure facilities on the shelf of the Arctic seas.

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2018年春天，通过遥感数据研究塞维纳亚地岛附近的冰山漂移

利用可见光波段的卫星观测，分析了2018年春季塞弗纳亚地岛群岛海岸外拉普捷夫海冰山的运动。如文中所示，安装在Landsat-8和Sentinel-2卫星上的辐射计数据可以监测上述北极地区春季的冰山漂移。因此，2018年3月至4月，在群岛附近检测到的冰山总数为4917座。4161座冰山在陆地冰面上，722座冰山随冰原漂移，其余32座冰山搁浅在冰原上。冰山的平均长度为88米;已知的最大的冰山位于马图谢维奇峡湾冰架附近的陆地冰上，长度为1240米。根据卫星资料，冰山的最大漂移速度等于29.5公里/天。这是在近水面(地面)风速达到20米/秒以上的情况下估计的。这项工作的目的是研究冰山的漂移，以便更准确地定义这个鲜为人知的北极地区的冰山运动动力学。研究发现，在固结冰盖的情况下，涉及冰山的冰原的漂移速度取决于驱动风力和风向。根据冰山的平均移动速度，将所有冰山分为三组:速度小于1 km/d的海岸带冰山;过渡带的冰山以1.3 ~ 1.6 km/d的速度移动;而过境区的冰山以2公里/天的速度较大。在每日卫星监测的基础上获得的冰山漂移特征可用于区域冰山漂移模型，以确保北极大陆架上的安全经济活动。此外，它们还可以应用于北冰洋大陆架基础设施设计的工程计算中。

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.