南极洲乔治王岛Dobrowolski冰川古冰川重建与地貌填图

IF 0.5 Q4 GEOGRAPHY, PHYSICAL

Revista Brasileira de Geomorfologia Pub Date : 2023-09-19 DOI:10.20502/rbg.v24i3.2425

Cleiva Perondi, Kátia Kellem da Rosa, Fabio José Guedes Magrani, Carina Petsch, Rosemary Vieira, Arthur Ayres Neto, Jefferson Cardia Simões

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引用次数: 0

摘要

本文旨在重建Dobrowolski冰川自小冰期(1400-1700年)至今的波动，Dobrowolski冰川是位于Admiralty Bay (King George Island, Antarctica)内部位置的潮汐冰川。冰川面积和长度的测量是基于多时相卫星图像和海底冰川地貌。小冰期至2014年冰川表面积变化D是估计的。冰碛河岸和古冰川重建提供了在公元2014年至公元2014年期间冰川表面积波动的证据。因此，建立了四个阶段的分析:第一阶段(第一部分)(1400年至1700年)，第一阶段(第二部分)(1700年至20世纪中期)，第二阶段(20世纪中期至20世纪80年代)，第三阶段(1980年至2000年)和第四阶段(2000年至2020年)。小冰期的气候触发了最后一次主要的冰川推进，它们的接地线位置由外部突出的冰碛垄记录。在接地线的主要冰川推进位置之后，由于变暖趋势和锚点的丧失，冰缘经历了更高的退缩率(第一阶段)。第二阶段(单元B)记录了在峡湾较深一点的活跃冰流背景下形成的远端和不连续的冰脊和冰川线。在第三阶段(C单元)，出现了冰川线条和陡坡，而地貌保存较少，显示出快速萎缩阶段。阶段IV的特征是不连续的冰碛脊(单元D)，此时冰川的年冰川面积损失最大。目前，加速收缩可能与海底山锚固(作为锚点)的丧失和升温有关。近300年来，u型山谷的几何形状也影响了冰川的收缩过程和冰川古水流的重新定向。20世纪中期至2020年的退缩率高于小冰期至20世纪中期的退缩率。

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Paleoglaciological reconstruction and geomorphological mapping of Dobrowolski Glacier, King George Island, Antarctica

The paper aims to reconstruct the fluctuations of Dobrowolski Glacier, a tidewater glacier located in the inner position of the Admiralty Bay (King George Island, Antarctica), from the Little Ice Age (1400-1700) until the present. Measurements of the glacier’s area and length were based on multitemporal satellite imagery and submarine glacial landforms. The glacier surface area variations between the Little Ice Age and 2014 A.D were estimated. Morainic banks and paleoglacial reconstructions provided evidence of fluctuations in the surface area of the glacier between PIG and 2014 AD. Therefore, four stages of analysis were established: Stage I (Part I) (1400 to 1700), Stage I (Part II) (1700 until the mid-20th century), Stage II (mid-20th century until the 1980s), Stage III (1980 to 2000), and Stage IV (2000 to 2020). The climate during the Little Ice Age triggered the last major glacial advance, and their grounding line position was recorded by an external and prominent morainic bank. After the major glacial advance position of the grounding line, the ice-margin has undergone higher retreat rates (stage I) as response to the warming trend and the loss of anchoring point. The stage II (Unit B) is recorded by distal and discontinuous morainal ridges and glacial lineations formed in the context of an active ice flow at a deeper point in the fjord. During stage III (Unit C) glacial lineations and steep slopes occur, while landforms are less preserved, revealing a fast shrinkage phase. Stage IV is characterized by discontinuous morainic ridges (Unit D), when the glacier presents the highest annual glacial area loss. Currently, the accelerated shrinkage may be linked to the loss of anchorage on seamounts (serving as pinning points) and increased warming. The U-shaped valley geometry has also influenced the glacier shrinkage processes and the redirection of glacial paleoflow during the last 300 years. The retreat rate to mid-20th century-2020 period is higher than Little Ice Age- mid-20th century period.

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来源期刊

Revista Brasileira de Geomorfologia GEOGRAPHY, PHYSICAL-

CiteScore

1.30

自引率

40.00%

发文量

审稿时长

16 weeks

期刊介绍： The Revista Brasileira de Geomorfologia are focused on research, analysis and application of knowledge for the development of models of large sets of relief; fluvial dynamics; the processes of aspects, such as erosion and mass movements and their impact; survey, assessment and recovery of degraded areas; surveys and assessments of natural resources; thematic mapping and integrated relief; environmental zoning; among other relevant aspects of the land relief on any scale. From a technical and instrumental basis for the development of these studies, studies that use instruments to the survey, the interpretation and generalization of data on various aspects of the Earth''s surface, including the forms of occupation and use (s) company (s) human (s). As well as the use and integration of methods and techniques that enable geo technical and instrumental character important in scientific production and the definition of public policies.