Correlations between components of the water balance and burned area reveal new insights for predicting forest fire area in the southwest United States

Williams, A. Park; Seager, Richard; Macalady, Alison K.; Berkelhammer, Max; Crimmins, Michael A.; Swetnam, Thomas W.; Trugman, Anna T.; Buenning, Nikolaus; Noone, David; McDowell, Nate G.; Hryniw, Natalia; Mora, Claudia I.; Rahn, Thom

We related measurements of annual burned area in the southwest United States during 1984–2013 to records of climate variability. Within forests, annual burned area correlated at least as strongly with spring–summer vapour pressure deficit (VPD) as with 14 other drought-related metrics, including more complex metrics that explicitly represent fuel moisture. Particularly strong correlations with VPD arise partly because this term dictates the atmospheric moisture demand. Additionally, VPD responds to moisture supply, which is difficult to measure and model regionally due to complex micrometeorology, land cover and terrain. Thus, VPD appears to be a simple and holistic indicator of regional water balance. Coupled with the well-known positive influence of prior-year cold season precipitation on fuel availability and connectivity, VPD may be utilised for burned area forecasts and also to infer future trends, though these are subject to other complicating factors such as land cover change and management. Assuming an aggressive greenhouse gas emissions scenario, climate models predict mean spring–summer VPD will exceed the highest recorded values in the southwest in nearly 40% of years by the middle of this century. These results forewarn of continued increases in burned forest area in the southwest United States, and likely elsewhere, when fuels are not limiting.


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Also Published In

International Journal of Wildland Fire

More About This Work

Academic Units
Lamont-Doherty Earth Observatory
Ocean and Climate Physics
Published Here
August 27, 2021