Forest fire threatens global carbon sinks and population centres under rising atmospheric water demand

Hamish Clarke; Rachael H. Nolan; Victor Resco De Dios; Ross Bradstock; Anne Griebel; Shiva Khanal; Matthias M. Boer

doi:10.1038/s41467-022-34966-3

Forest fire threatens global carbon sinks and population centres under rising atmospheric water demand

Hamish Clarke, Rachael H. Nolan, Victor Resco De Dios, Ross Bradstock, Anne Griebel, Shiva Khanal, Matthias M. Boer

Research output: Contribution to journal › Article › peer-review

103 Citations (Scopus)

Abstract

Levels of fire activity and severity that are unprecedented in the instrumental record have recently been observed in forested regions around the world. Using a large sample of daily fire events and hourly climate data, here we show that fire activity in all global forest biomes responds strongly and predictably to exceedance of thresholds in atmospheric water demand, as measured by maximum daily vapour pressure deficit. The climatology of vapour pressure deficit can therefore be reliably used to predict forest fire risk under projected future climates. We find that climate change is projected to lead to widespread increases in risk, with at least 30 additional days above critical thresholds for fire activity in forest biomes on every continent by 2100 under rising emissions scenarios. Escalating forest fire risk threatens catastrophic carbon losses in the Amazon and major population health impacts from wildfire smoke in south Asia and east Africa.

Original language	English
Article number	7161
Number of pages	10
Journal	Nature Communications
Volume	13
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-34966-3
Publication status	Published - Dec 2022

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Cite this

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abstract = "Levels of fire activity and severity that are unprecedented in the instrumental record have recently been observed in forested regions around the world. Using a large sample of daily fire events and hourly climate data, here we show that fire activity in all global forest biomes responds strongly and predictably to exceedance of thresholds in atmospheric water demand, as measured by maximum daily vapour pressure deficit. The climatology of vapour pressure deficit can therefore be reliably used to predict forest fire risk under projected future climates. We find that climate change is projected to lead to widespread increases in risk, with at least 30 additional days above critical thresholds for fire activity in forest biomes on every continent by 2100 under rising emissions scenarios. Escalating forest fire risk threatens catastrophic carbon losses in the Amazon and major population health impacts from wildfire smoke in south Asia and east Africa.",

author = "Hamish Clarke and Nolan, {Rachael H.} and {Resco De Dios}, Victor and Ross Bradstock and Anne Griebel and Shiva Khanal and Boer, {Matthias M.}",

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AU - Clarke, Hamish

AU - Nolan, Rachael H.

AU - Resco De Dios, Victor

AU - Bradstock, Ross

AU - Griebel, Anne

AU - Khanal, Shiva

AU - Boer, Matthias M.

PY - 2022/12

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AB - Levels of fire activity and severity that are unprecedented in the instrumental record have recently been observed in forested regions around the world. Using a large sample of daily fire events and hourly climate data, here we show that fire activity in all global forest biomes responds strongly and predictably to exceedance of thresholds in atmospheric water demand, as measured by maximum daily vapour pressure deficit. The climatology of vapour pressure deficit can therefore be reliably used to predict forest fire risk under projected future climates. We find that climate change is projected to lead to widespread increases in risk, with at least 30 additional days above critical thresholds for fire activity in forest biomes on every continent by 2100 under rising emissions scenarios. Escalating forest fire risk threatens catastrophic carbon losses in the Amazon and major population health impacts from wildfire smoke in south Asia and east Africa.

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Forest fire threatens global carbon sinks and population centres under rising atmospheric water demand

Abstract

Bibliographical note

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