Abstract
High topographic heterogeneity and complex mechanisms between the atmosphere and the ground create unique hydro-climatic processes over mountainous regions. Based on in situ observations, we present the spatial variability of ground surface temperature (GST) in the Khentii Mountains of northern Mongolia, which is situated at the southern fringe of the Eurasian permafrost zone. Changes in the hydrothermal regime of the active layer were investigated in association with changing climate and wildfire effects. The results reveal that the GST tends to increase continuously since 2011 in both thawing and freezing seasons, and varies significantly within a short horizontal distance, particularly during the thawing season. Extreme weather events, such as drought and heavy snowfall, amplify the increase in the ground temperature and deepen the seasonal thawing depth. The fire-induced loss in organic layer resulted in a greater heat penetration deeper into the ground and unbalanced the moisture distribution. Overall, the thawing depth is greater by >1.7 m under severely burned forest, compared to unburned forest. Given that about 30% of the boreal forest was affected by wildfire in the study area, the ground thermal regime changed considerably. The findings suggest that the combination of regional temperature rise and more frequent extreme weather and wildfire events in the region triggers permafrost degradation and alters the hydrothermal regime in the future.
Highlights
The boreal forest biome in Siberia largely overlaps with the Eurasian discontinuous permafrost zone
Degrading permafrost due to rising air temperature is already evident in the southern boundary of Siberia, as well as on a global scale [3,4,5]
We present our preliminary results on the response of ground hydrothermal regime and permafrost stability to a combination of wildfire and extreme climatic events in the Khentii Mountains, northern Mongolia
Summary
The boreal forest biome in Siberia largely overlaps with the Eurasian discontinuous permafrost zone. Degrading permafrost due to rising air temperature is already evident in the southern boundary of Siberia (northern Mongolia), as well as on a global scale [3,4,5]. The moss layer underneath boreal forest plays a significant role in creating cold subsurface conditions during the thawing season, when air temperature is above 0 ◦ C. This heat insulation effect of the organic materials between the atmosphere and the ground surface is due to its low thermal conductivity (K), favoring permafrost presence. During the freezing season when air temperature remains below 0 ◦ C, the seasonal snow cover has the reverse insulating
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