Climate change has increased the odds of extreme regional forest fire years globally

John T. Abatzoglou; Crystal A. Kolden; Alison C. Cullen; Mojtaba Sadegh; Emily L. Williams; Marco Turco; Matthew W. Jones

doi:10.1038/s41467-025-61608-1

Climate change has increased the odds of extreme regional forest fire years globally

John T. Abatzoglou, Crystal A. Kolden, Alison C. Cullen, Mojtaba Sadegh, Emily L. Williams, Marco Turco, Matthew W. Jones

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Abstract

Regions across the globe have experienced devastating fire years in the past decade with far-reaching impacts. Here, we examine the role of antecedent and concurrent climate variability in enabling extreme regional fire years across global forests. These extreme years commonly coincided with extreme (1-in-15-year) fire weather indices (FWI) and featured a four and five-fold increase in the number of large fires and fire carbon emissions, respectively, compared with non-extreme years. Years with such extreme FWI metrics are 88-152% more likely across global forested lands under a contemporary (2011–2040) climate compared to a quasi-preindustrial (1851–1900) climate, with the most pronounced increased risk in temperate and Amazonian forests. Our results show that human-caused climate change is raising the odds of extreme climate-driven fire years across forested regions of the globe, necessitating proactive measures to mitigate risks and adapt to extreme fire years.

Original language	English
Article number	6390
Journal	Nature Communications
Volume	16
DOIs	https://doi.org/10.1038/s41467-025-61608-1
Publication status	Published - 10 Jul 2025

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Cite this

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title = "Climate change has increased the odds of extreme regional forest fire years globally",

abstract = "Regions across the globe have experienced devastating fire years in the past decade with far-reaching impacts. Here, we examine the role of antecedent and concurrent climate variability in enabling extreme regional fire years across global forests. These extreme years commonly coincided with extreme (1-in-15-year) fire weather indices (FWI) and featured a four and five-fold increase in the number of large fires and fire carbon emissions, respectively, compared with non-extreme years. Years with such extreme FWI metrics are 88-152% more likely across global forested lands under a contemporary (2011–2040) climate compared to a quasi-preindustrial (1851–1900) climate, with the most pronounced increased risk in temperate and Amazonian forests. Our results show that human-caused climate change is raising the odds of extreme climate-driven fire years across forested regions of the globe, necessitating proactive measures to mitigate risks and adapt to extreme fire years.",

author = "Abatzoglou, {John T.} and Kolden, {Crystal A.} and Cullen, {Alison C.} and Mojtaba Sadegh and Williams, {Emily L.} and Marco Turco and Jones, {Matthew W.}",

note = "Data availability: Historical meteorological data used herein from ERA-5 are available from (https://cds.climate.copernicus.eu/), and climate projections used in the paper are available at https://www.research-collection.ethz.ch/handle/20.500.11850/583391. Gridded burned area data is available from the MODIS global burned area product MCD64A1 (https://modis-fire.umd.edu/ba.html). The Global Fire Atlas and GFED4s fire carbon emissions are available at https://zenodo.org/records/11400062 and https://www.geo.vu.nl/~gwerf/GFED/GFED4/, respectively. Code availability: No specialized code for data analysis was developed for this study. Funding information: The work was supported through grants from the NSF Growing Convergence Research Program (OAI-2019762) to J.T.A. and A.C.C., Department of Interior{\textquoteright}s Joint Fire Science Program (21-2-01-1 and 21-2-01-3) to J.T.A., M.S., and E.W. and UK Natural Environment Research Council (NERC) grant NE/ V01417X/1 to M.W.J.",

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AU - Williams, Emily L.

AU - Turco, Marco

AU - Jones, Matthew W.

N1 - Data availability: Historical meteorological data used herein from ERA-5 are available from (https://cds.climate.copernicus.eu/), and climate projections used in the paper are available at https://www.research-collection.ethz.ch/handle/20.500.11850/583391. Gridded burned area data is available from the MODIS global burned area product MCD64A1 (https://modis-fire.umd.edu/ba.html). The Global Fire Atlas and GFED4s fire carbon emissions are available at https://zenodo.org/records/11400062 and https://www.geo.vu.nl/~gwerf/GFED/GFED4/, respectively. Code availability: No specialized code for data analysis was developed for this study. Funding information: The work was supported through grants from the NSF Growing Convergence Research Program (OAI-2019762) to J.T.A. and A.C.C., Department of Interior’s Joint Fire Science Program (21-2-01-1 and 21-2-01-3) to J.T.A., M.S., and E.W. and UK Natural Environment Research Council (NERC) grant NE/ V01417X/1 to M.W.J.

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N2 - Regions across the globe have experienced devastating fire years in the past decade with far-reaching impacts. Here, we examine the role of antecedent and concurrent climate variability in enabling extreme regional fire years across global forests. These extreme years commonly coincided with extreme (1-in-15-year) fire weather indices (FWI) and featured a four and five-fold increase in the number of large fires and fire carbon emissions, respectively, compared with non-extreme years. Years with such extreme FWI metrics are 88-152% more likely across global forested lands under a contemporary (2011–2040) climate compared to a quasi-preindustrial (1851–1900) climate, with the most pronounced increased risk in temperate and Amazonian forests. Our results show that human-caused climate change is raising the odds of extreme climate-driven fire years across forested regions of the globe, necessitating proactive measures to mitigate risks and adapt to extreme fire years.

AB - Regions across the globe have experienced devastating fire years in the past decade with far-reaching impacts. Here, we examine the role of antecedent and concurrent climate variability in enabling extreme regional fire years across global forests. These extreme years commonly coincided with extreme (1-in-15-year) fire weather indices (FWI) and featured a four and five-fold increase in the number of large fires and fire carbon emissions, respectively, compared with non-extreme years. Years with such extreme FWI metrics are 88-152% more likely across global forested lands under a contemporary (2011–2040) climate compared to a quasi-preindustrial (1851–1900) climate, with the most pronounced increased risk in temperate and Amazonian forests. Our results show that human-caused climate change is raising the odds of extreme climate-driven fire years across forested regions of the globe, necessitating proactive measures to mitigate risks and adapt to extreme fire years.

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ER -

Climate change has increased the odds of extreme regional forest fire years globally

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Climate change impacts on wildfire ignitions by lightning and the safe management of landscape fuels

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Climate change has increased the odds of extreme regional forest fire years globally

Abstract

UN SDGs

Access to Document

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Climate change impacts on wildfire ignitions by lightning and the safe management of landscape fuels

Cite this