Escalating wildfires in Siberia driven by multiple climate feedbacks under a warming Arctic

Wildfire in Siberia is of paramount importance in the carbon cycle and climate change as it is a major disturbance in the pan-Arctic ecosystems. In recent decades, the Siberian wildfire regime has been changing; however, less is known about the key climatic drivers and the underlying feedback over t...

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Main Authors: Huang, Xin, Xue, Lian, Ding, Aijun
Format: Other/Unknown Material
Language:unknown
Published: California Digital Library (CDL) 2022
Subjects:
Arctic
Climate change
Siberia
Online Access:http://dx.doi.org/10.31223/x51d2m
id crescholarship:10.31223/x51d2m
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spelling crescholarship:10.31223/x51d2m 2024-04-07T07:49:37+00:00 Escalating wildfires in Siberia driven by multiple climate feedbacks under a warming Arctic Huang, Xin Xue, Lian Ding, Aijun 2022 http://dx.doi.org/10.31223/x51d2m unknown California Digital Library (CDL) posted-content 2022 crescholarship https://doi.org/10.31223/x51d2m 2024-03-08T03:58:03Z Wildfire in Siberia is of paramount importance in the carbon cycle and climate change as it is a major disturbance in the pan-Arctic ecosystems. In recent decades, the Siberian wildfire regime has been changing; however, less is known about the key climatic drivers and the underlying feedback over these vulnerable fire-prone landscapes. Here, based on ground-based and satellite observations and meteorological reanalysis data during the past two decades (2002–2021), we find that central Siberia features the most prominent wildfire escalation and poleward expansion. Such a shift in wildfires is closely related to drying soil moisture under a fast-warming Arctic. Our results show that a warming air temperature and weakened meridional moisture flux substantially suppress precipitation and are responsible for an increasing hydrological drought in central Siberia. We also reveal an unexpected self-amplifying feedback induced by smoke aerosol via modifying cloud microphysical properties, which further compounds wildfires in Siberia. As the Arctic warming is projected to continue, wildfires in this region are estimated to be in-tensified by 200–350% by the end of this century. This work identifies main climate drivers and feedback mechanism for the escalating wildfire risk in Siberia since the onset of this century, highlighting the importance of risk management and fire-climate adaptation in this region. Other/Unknown Material Arctic Climate change Siberia eScholarship Repository (University of California) Arctic
institution Open Polar
collection eScholarship Repository (University of California)
op_collection_id crescholarship
language unknown
description Wildfire in Siberia is of paramount importance in the carbon cycle and climate change as it is a major disturbance in the pan-Arctic ecosystems. In recent decades, the Siberian wildfire regime has been changing; however, less is known about the key climatic drivers and the underlying feedback over these vulnerable fire-prone landscapes. Here, based on ground-based and satellite observations and meteorological reanalysis data during the past two decades (2002–2021), we find that central Siberia features the most prominent wildfire escalation and poleward expansion. Such a shift in wildfires is closely related to drying soil moisture under a fast-warming Arctic. Our results show that a warming air temperature and weakened meridional moisture flux substantially suppress precipitation and are responsible for an increasing hydrological drought in central Siberia. We also reveal an unexpected self-amplifying feedback induced by smoke aerosol via modifying cloud microphysical properties, which further compounds wildfires in Siberia. As the Arctic warming is projected to continue, wildfires in this region are estimated to be in-tensified by 200–350% by the end of this century. This work identifies main climate drivers and feedback mechanism for the escalating wildfire risk in Siberia since the onset of this century, highlighting the importance of risk management and fire-climate adaptation in this region.
format Other/Unknown Material
author Huang, Xin
Xue, Lian
Ding, Aijun
spellingShingle Huang, Xin
Xue, Lian
Ding, Aijun
Escalating wildfires in Siberia driven by multiple climate feedbacks under a warming Arctic
author_facet Huang, Xin
Xue, Lian
Ding, Aijun
author_sort Huang, Xin
title Escalating wildfires in Siberia driven by multiple climate feedbacks under a warming Arctic
title_short Escalating wildfires in Siberia driven by multiple climate feedbacks under a warming Arctic
title_full Escalating wildfires in Siberia driven by multiple climate feedbacks under a warming Arctic
title_fullStr Escalating wildfires in Siberia driven by multiple climate feedbacks under a warming Arctic
title_full_unstemmed Escalating wildfires in Siberia driven by multiple climate feedbacks under a warming Arctic
title_sort escalating wildfires in siberia driven by multiple climate feedbacks under a warming arctic
publisher California Digital Library (CDL)
publishDate 2022
url http://dx.doi.org/10.31223/x51d2m
geographic Arctic
geographic_facet Arctic
genre Arctic
Climate change
Siberia
genre_facet Arctic
Climate change
Siberia
op_doi https://doi.org/10.31223/x51d2m
_version_ 1795664005118820352

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