Observed permafrost thawing and disappearance near the altitudinal limit of permafrost in the Qilian Mountains

Permafrost degradation has been widely reported on the Tibetan Plateau (TP). However, directly observed evidence of permafrost thawing processes and degradation rates are very limited, although it is expected to be prevalent near the periphery of a permafrost area. Here, we report permafrost changes...

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Bibliographic Details
Published in:Advances in Climate Change Research
Main Authors: Wen Sun, Tingjun Zhang, Gary D. Clow, Yan-Hua Sun, Wen-Yu Zhao, Ben-Ben Liang, Cheng-Yan Fan, Xiao-Qing Peng, Bin Cao
Format: Article in Journal/Newspaper
Language:English
Published: KeAi Communications Co., Ltd. 2022
Subjects:
Permafrost
Permafrost degradation
Permafrost lateral thawing
Qilian Mountains
Meteorology. Climatology
QC851-999
Social sciences (General)
H1-99
Active layer thickness
permafrost
Online Access:https://doi.org/10.1016/j.accre.2022.08.004
https://doaj.org/article/0ce5ff429b124dbbbd96aa31daefc507
Description
Summary:Permafrost degradation has been widely reported on the Tibetan Plateau (TP). However, directly observed evidence of permafrost thawing processes and degradation rates are very limited, although it is expected to be prevalent near the periphery of a permafrost area. Here, we report permafrost changes and disappearance in the Qilian Mountains (northeastern TP) based on three boreholes instrumented along a 100 m transect during 2014–2021. Our results show that permafrost has significantly degraded in the study area: the mean downward thawing rate from the permafrost table was about 0.16 m per year while the mean upward thawing rate from the permafrost base was about 0.23 m per year. We estimate the mean lateral degradation rate of permafrost in this area was ∼4.14 m per year. More dramatically, the 1.5 m thick permafrost layer at one of the boreholes thawed completely between April of 2018 and December of 2019. Our results indicate that changes in climatic condition may have played only a limited role in controlling the active layer thickness in the vicinity of the altitudinal limit of permafrost; moisture content and soil conditions play key roles in site-specific permafrost thawing. This study provides new quantitative insights for understanding changes near the altitudinal limit of permafrost, and we suggest that land surface models or Earth system model studies of the lateral heat exchanges should be implemented in order to better represent permafrost thawing processes.

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