Life Cycles and Polycyclicity of Mega Retrogressive Thaw Slumps in Arctic Permafrost Revealed by 2D/3D Geophysics and Long-Term Retreat Monitoring

IF 3.5 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY
Michael Krautblatter, Michael Angelopoulos, Wayne H. Pollard, Hugues Lantuit, Josefine Lenz, Michael Fritz, Nicole Couture, Saskia Eppinger
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Abstract

Mega retrogressive thaw slumps (MRTS, >106 m3) are a major threat to Arctic infrastructure, alter regional biogeochemistry, and impact Arctic carbon budgets. However, processes initiating and reactivating MRTS are insufficiently understood. We hypothesize that MRTS preferentially develop a polycyclic behavior because the material is thermally and mechanically prepared for subsequent generation failure. In contrast to remote sensing, geophysical reconnaissance reveals the inner structure and relative thermal state of MRTS decameters beneath slump surfaces, potentially controlling polycyclicity. Based on their life cycle development, five (M)RTS were studied on Herschel Island, an MRTS hotspot on the Canadian Beaufort coast. We combine >2 km of electrical resistivity tomography (ERT), 500 m of ground-penetrating radar (GPR) and annual monitoring of headwall retreat from 2004 to 2013 to reveal the thermal state, internal structure, and volume loss of slumps. ERT data were calibrated with unfrozen-frozen transitions from frost probing of active layer thickness and shallow boreholes. In initial stage MRTS, ERT displays surficial thermal perturbations a few meters deep, coincident with recent mud pool and mud flow development. In early stage polycyclic MRTS, ERT shows decameter deep-reaching thermal perturbations persisting even 300 years after the last activation. In peak-stage polycyclic MRTS, 3D-ERT highlights actively extending deep-reaching thermal perturbations caused by gully incisions, mud slides and mud flows. GPR and headwall monitoring reveal structural disturbance by historical mud flows, ice-rich permafrost, and a decadal quantification of headwall retreat and slump floor erosion. We show that geophysical signatures identify long-lasting thermal and mechanical disturbances in MRTS predefining their susceptibility to polycyclic reactivation.

Abstract Image

二维/三维地球物理学和长期退缩监测揭示的北极永久冻土特大逆行解冻坍塌的生命周期和多周期性
特大逆行解冻坍塌(MRTS,106 立方米)对北极基础设施构成重大威胁,改变区域生物地球化学,影响北极碳预算。然而,人们对引发和重新激活 MRTS 的过程了解不足。我们假设 MRTS 优先发展多环行为,因为材料在热学和机械学上为随后的生成故障做好了准备。与遥感不同的是,地球物理勘察揭示了坍落度表面下的 MRTS 分块的内部结构和相对热状态,这有可能控制多环性。根据其生命周期的发展,我们在加拿大波弗特海岸的 MRTS 热区赫歇尔岛研究了五个(M)RTS。我们结合了 2 公里的电阻率层析成像(ERT)、500 米的探地雷达(GPR)以及 2004 年至 2013 年期间对顶壁退缩的年度监测,揭示了坍方的热状态、内部结构和体积损失。ERT 数据与活动层厚度霜冻探测和浅层钻孔的未冻结-冻结过渡数据进行了校准。在初始阶段的 MRTS 中,ERT 显示了几米深的表层热扰动,与近期泥浆池和泥流的发展相吻合。在多环 MRTS 早期阶段,ERT 显示的十米深热扰动甚至在最后一次激活 300 年后仍持续存在。在峰值阶段的多环 MRTS 中,3D-ET 突出显示了由沟谷切入、泥石流和泥石流造成的热扰动在不断延伸。GPR 和顶壁监测显示了历史泥流、富冰永久冻土以及顶壁退缩和坍塌底板侵蚀的十年量化结构扰动。我们的研究表明,地球物理特征可以识别 MRTS 中持久的热扰动和机械扰动,从而预先确定其对多环再活化的敏感性。
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来源期刊
Journal of Geophysical Research: Earth Surface
Journal of Geophysical Research: Earth Surface Earth and Planetary Sciences-Earth-Surface Processes
CiteScore
6.30
自引率
10.30%
发文量
162
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