Response of Seasonally Frozen Ground to Climate Changes in the Northeastern Qinghai-Tibet Plateau

The effects of climate change on permafrost have been well documented in many studies, whereas the effect of climate change on seasonally frozen ground (SFG) is still poorly understood. We used the observed daily freeze depth of SFG and environmental factors data from the period 2007-2016 to examine...

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Main Authors: Zhao, ZH, Fu, RY, Liu, JJ, Dai, LC, Guo, XW, Du, YG, Hu, ZM, Cao, GM
Format: Report
Language:unknown
Published: 2022
Subjects:
permafrost
Online Access:http://210.75.249.4/handle/363003/61155
id ftchinacascnwipb:oai:210.75.249.4:363003/61155
record_format openpolar
spelling ftchinacascnwipb:oai:210.75.249.4:363003/61155 2023-05-15T17:58:11+02:00 Response of Seasonally Frozen Ground to Climate Changes in the Northeastern Qinghai-Tibet Plateau Zhao, ZH Fu, RY Liu, JJ Dai, LC Guo, XW Du, YG Hu, ZM Cao, GM 2022 http://210.75.249.4/handle/363003/61155 unknown FRONTIERS IN ENVIRONMENTAL SCIENCE http://210.75.249.4/handle/363003/61155 null 期刊论文 2022 ftchinacascnwipb 2023-03-26T20:46:56Z The effects of climate change on permafrost have been well documented in many studies, whereas the effect of climate change on seasonally frozen ground (SFG) is still poorly understood. We used the observed daily freeze depth of SFG and environmental factors data from the period 2007-2016 to examine the seasonal and inter-annual variation of SFG. We quantitatively evaluated the effects of environmental factors on SFG using a boosted regression tree analysis. The results show that, on a seasonal scale, the lower layer soil frost starts freezing in mid-November, with the maximum freeze depth occurring in late March (209 cm), and then begins to thaw in both the lower and upper layers. We identified four stages of the freeze-thaw cycle: the non-frozen phase, initial freezing, deep freezing, and thawing. Furthermore, the thawing process of SFG mainly took place in the upper layer, but the freezing rate of the lower layer from mid-November to early February was similar to the thawing rate of late April to late June. On the inter-annual scale, the maximum freeze depth showed a significant increasing trend (p < 0.05). However, the freeze-thaw duration declined significantly (p < 0.05), which was correlated with the decrease in the period when surface soil temperature is below 0 degrees C. The mean soil temperature and soil heat flux were the most important environmental indicators affecting seasonal variation of SFG depth, and the cumulative negative air and soil temperatures were the dominant factors affecting inter-annual variation of maximum freeze depth. Our results might provide insight into predicting hydrological and ecological responses to future climate change in frozen-ground regions. Report permafrost Northwest Institute of Plateau Biology: NWIPB OpenIR (Chinese Academy of Sciences)
institution Open Polar
collection Northwest Institute of Plateau Biology: NWIPB OpenIR (Chinese Academy of Sciences)
op_collection_id ftchinacascnwipb
language unknown
description The effects of climate change on permafrost have been well documented in many studies, whereas the effect of climate change on seasonally frozen ground (SFG) is still poorly understood. We used the observed daily freeze depth of SFG and environmental factors data from the period 2007-2016 to examine the seasonal and inter-annual variation of SFG. We quantitatively evaluated the effects of environmental factors on SFG using a boosted regression tree analysis. The results show that, on a seasonal scale, the lower layer soil frost starts freezing in mid-November, with the maximum freeze depth occurring in late March (209 cm), and then begins to thaw in both the lower and upper layers. We identified four stages of the freeze-thaw cycle: the non-frozen phase, initial freezing, deep freezing, and thawing. Furthermore, the thawing process of SFG mainly took place in the upper layer, but the freezing rate of the lower layer from mid-November to early February was similar to the thawing rate of late April to late June. On the inter-annual scale, the maximum freeze depth showed a significant increasing trend (p < 0.05). However, the freeze-thaw duration declined significantly (p < 0.05), which was correlated with the decrease in the period when surface soil temperature is below 0 degrees C. The mean soil temperature and soil heat flux were the most important environmental indicators affecting seasonal variation of SFG depth, and the cumulative negative air and soil temperatures were the dominant factors affecting inter-annual variation of maximum freeze depth. Our results might provide insight into predicting hydrological and ecological responses to future climate change in frozen-ground regions.
format Report
author Zhao, ZH
Fu, RY
Liu, JJ
Dai, LC
Guo, XW
Du, YG
Hu, ZM
Cao, GM
spellingShingle Zhao, ZH
Fu, RY
Liu, JJ
Dai, LC
Guo, XW
Du, YG
Hu, ZM
Cao, GM
Response of Seasonally Frozen Ground to Climate Changes in the Northeastern Qinghai-Tibet Plateau
author_facet Zhao, ZH
Fu, RY
Liu, JJ
Dai, LC
Guo, XW
Du, YG
Hu, ZM
Cao, GM
author_sort Zhao, ZH
title Response of Seasonally Frozen Ground to Climate Changes in the Northeastern Qinghai-Tibet Plateau
title_short Response of Seasonally Frozen Ground to Climate Changes in the Northeastern Qinghai-Tibet Plateau
title_full Response of Seasonally Frozen Ground to Climate Changes in the Northeastern Qinghai-Tibet Plateau
title_fullStr Response of Seasonally Frozen Ground to Climate Changes in the Northeastern Qinghai-Tibet Plateau
title_full_unstemmed Response of Seasonally Frozen Ground to Climate Changes in the Northeastern Qinghai-Tibet Plateau
title_sort response of seasonally frozen ground to climate changes in the northeastern qinghai-tibet plateau
publishDate 2022
url http://210.75.249.4/handle/363003/61155
genre permafrost
genre_facet permafrost
op_relation FRONTIERS IN ENVIRONMENTAL SCIENCE
http://210.75.249.4/handle/363003/61155
op_rights null
_version_ 1766166736096198656

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