Remote Sensing (Jul 2024)

Observed Retrogressive Thaw Slump Evolution in the Qilian Mountains

  • Xingyun Liu,
  • Xiaoqing Peng,
  • Yongyan Zhang,
  • Oliver W. Frauenfeld,
  • Gang Wei,
  • Guanqun Chen,
  • Yuan Huang,
  • Cuicui Mu,
  • Jun Du

DOI
https://doi.org/10.3390/rs16132490
Journal volume & issue
Vol. 16, no. 13
p. 2490

Abstract

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Climate warming can lead to permafrost degradation, potentially resulting in slope failures such as retrogressive thaw slumps (RTSs). The formation of and changes in RTSs could exacerbate the degradation of permafrost and the environment in general. The mechanisms of RTS progression and the potential consequences on the analogous freeze–thaw cycle are not well understood, owing partly to necessitating field work under harsh conditions and with high costs. Here, we used multi-source remote sensing and field surveys to quantify the changes in an RTS on Eboling Mountain in the Qilian Mountain Range in west-central China. Based on optical remote sensing and SBAS-InSAR measurements, we analyzed the RTS evolution and the underlying drivers, combined with meteorological observations. The RTS expanded from 56 m2 in 2015 to 4294 m2 in 2022, growing at a rate of 1300 m2/a to its maximum in 2018 and then decreasing. Changes in temperature and precipitation play a dominant role in the evolution of the RTS, and the extreme weather in 2016 may also be a primary contributor to the accelerated growth, with an average deformation of −8.3 mm during the thawing period, which decreased slope stability. The RTS evolved more actively during the thawing and early freezing process, with earthquakes having potentially contributed further to RTS evolution. We anticipate that the rate of RTS evolution is likely to increase in the coming years.

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