Research progress on hydrological effects of permafrost degradation in the Northern Hemisphere

•Review the historical research progress on permafrost degradation from 1990-2022.•Assess the cascading effects of permafrost degradation from three topics.•The never-monitored permafrost areas in the Northern Hemisphere account for 7%.•Monitor permafrost degradation at point, slope, watershed, and...

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Bibliographic Details
Published in:Geoderma 2023-10, Vol.438, p.116629, Article 116629
Main Authors: Li, Wenwen, Yan, Denghua, Weng, Baisha, Zhu, Lin
Format: Article
Language:English
Subjects:
altitude
China
climate
Climate warming
Cold regions
Cryosphere
evapotranspiration
grasslands
humans
hydrologic cycle
Hydrological effect
isotopes
latitude
lightning
permafrost
Permafrost degradation
runoff
sea level
soil water
Soil water content
streams
wildfires
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Summary:•Review the historical research progress on permafrost degradation from 1990-2022.•Assess the cascading effects of permafrost degradation from three topics.•The never-monitored permafrost areas in the Northern Hemisphere account for 7%.•Monitor permafrost degradation at point, slope, watershed, and global scales. Permafrost degradation alters the flow rate, direction, and storage capacity of soil moisture, affecting ecohydrological effects and climate systems, and posing a potential threat to natural and human systems. The most widely distributed permafrost regions are coastal, high-latitudes and high-altitudes (mainly by the Qinghai-Tibet Plateau). Past studies have demonstrated that permafrost degradation in these regions lacks sorting out regional driving factors, assessing cascading effects on the hydrological environment and monitoring methods. To address this, we reviewed the historical research situation and major topics of permafrost degradation from 1990 to 2022. We analyzed the spatio-temporal dynamics and driving mechanism of permafrost degradation. Then, we comprehensively discussed the effects of permafrost degradation on the soil physical structure and hydraulic properties, soil microorganisms and local vegetation, soil evapotranspiration and stream runoff, and integrated ecohydrological effects. Permafrost field site data were then collected from existing findings and methods for direct or indirect monitoring of permafrost changes at different scales. These results revealed that the research on the hydrological effects of permafrost change was mainly centered on the soil. In addition, regional environmental factors driving permafrost degradation were inconsistent mainly in coastal regions influenced by sea level, high-latitude regions influenced by lightning and wildfire, and high-altitude regions influenced by topography. Permafrost degradation promoted horizontal and/or vertical hydrological connectivity, threatening the succession of high latitude vegetation communities and the transition from high altitude grassland to desert ecosystems, causing regional water imbalances would mitigate or amplify the ability of integrated ecohydrological benefits to cope with climate warming. The never-monitored permafrost area was 1.55×106 km2, but the limitations of using data for the same period remained a challenging task for soil moisture monitoring. Finally, future research should enhance the observation of driving factors at the monitoring site an
ISSN:0016-7061
1872-6259
DOI:10.1016/j.geoderma.2023.116629