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Nature Research, npj Climate and Atmospheric Science, 1(5), 2022

DOI: 10.1038/s41612-022-00248-4

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Global increase in wildfire potential from compound fire weather and drought

This paper is made freely available by the publisher.
This paper is made freely available by the publisher.

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Abstract

AbstractWildfire can cause significant adverse impacts to society and the environment. Weather and climate play an important role in modulating wildfire activity. We explore the joint occurrence of global fire weather and meteorological drought using a compound events framework. We show that, for much of the globe, burned area increases when periods of heightened fire weather compound with dry antecedent conditions. Regions associated with wildfire disasters, such as southern Australia and the western USA, are prone to experiencing years of compound drought and fire weather. Such compound events have increased in frequency for much of the globe, driven primarily by increases in fire weather rather than changes in precipitation. El Ni$\tilde{{{{\rm{n}}}}}$ n ̃ o Southern Oscillation is associated with widespread, spatially compounding drought and fire weather. In the Northern Hemisphere, a La Ni$\tilde{{{{\rm{n}}}}}$ n ̃ a signature is evident, whereas El Ni$\tilde{{{{\rm{n}}}}}$ n ̃ o is associated with such events in the tropics and, to a lesser degree, the Southern Hemisphere. Other climate modes and regional patterns of atmospheric circulation are also important, depending on the region. We show that the lengths of the fire weather seasons in eastern Australia and western North America have increased substantially since 2000, raising the likelihood of overlapping fire weather events in these regions. These cross-hemispheric events may be linked to the occurrence of El Ni$\tilde{{{{\rm{n}}}}}$ n ̃ o, although the sea-surface temperature magnitudes are small. Instead, it is likely that anthropogenic climate change is the primary driver of these changes.