Quantifying the environmental limits to fire spread in grassy ecosystems

Modeling fire spread as an infection process is intuitive: An ignition lights a patch of fuel, which infects its neighbor, and so on. Infection models produce nonlinear thresholds, whereby fire spreads only when fuel connectivity and infection probability are sufficiently high. These thresholds are...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 119; no. 26; pp. 1 - 7
Main Authors Cardoso, Anabelle W., Archibald, Sally, Bond, William J., Coetsee, Corli, Forrest, Matthew, Govender, Navashni, Lehmann, David, Makaga, Loïc, Mpanza, Nokukhanya, Ndong, Josué Edzang, Pambo, Aurélie Flore Koumba, Strydom, Tercia, Tilman, David, Wragg, Peter D., Staver, A. Carla
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences 28.06.2022
Subjects
Annual precipitation
Biological Sciences
Biomass burning
Climate
Climate Change
Ecosystem
Environment models
Fuels
Infections
Models, Theoretical
Moisture effects
National parks
Poaceae
Precipitation
South Africa
Thresholds
Vapor pressure
Wildfires
South Africa
fire model
infection model
percolation
fire thresholds
fuel moisture
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Summary:Modeling fire spread as an infection process is intuitive: An ignition lights a patch of fuel, which infects its neighbor, and so on. Infection models produce nonlinear thresholds, whereby fire spreads only when fuel connectivity and infection probability are sufficiently high. These thresholds are fundamental both to managing fire and to theoretical models of fire spread, whereas applied fire models more often apply quasiempirical approaches. Here, we resolve this tension by quantifying thresholds in fire spread locally, using field data from individual fires (n = 1,131) in grassy ecosystems across a precipitation gradient (496 to 1,442 mm mean annual precipitation) and evaluating how these scaled regionally (across 533 sites) and across time (1989 to 2012 and 2016 to 2018) using data from Kruger National Park in South Africa. An infection model captured observed patterns in individual fire spread better than competing models. The proportion of the landscape that burned was well described by measurements of grass biomass, fuel moisture, and vapor pressure deficit. Regionally, averaging across variability resulted in quasi-linear patterns. Altogether, results suggest that models aiming to capture fire responses to global change should incorporate nonlinear fire spread thresholds but that linear approximations may sufficiently capture medium-term trends under a stationary climate.
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Edited by Alan Hastings, University of California, Davis, CA; received June 4, 2021; accepted April 8, 2022
Author contributions: A.W.C., S.A., and A.C.S. designed research; A.W.C., S.A., W.J.B., C.C., N.G., D.L., L.M., N.M., J.E.N., A.F.K.P., T.S., D.T., P.D.W., and A.C.S. performed research; A.W.C., S.A., and A.C.S. analyzed data; and A.W.C., S.A., W.J.B., C.C., M.F., N.G., D.L., T.S., D.T., P.W., and A.C.S. wrote the paper.
ISSN:0027-8424
1091-6490
1091-6490
DOI:10.1073/pnas.2110364119