Abstract
Two extreme wind-driven wildfire events impacted California in late 2017, leading to 46 fatalities and thousands of structures lost. This study characterizes the meteorological and climatological factors that drove and enabled these wildfire events and quantifies their rarity over the observational record. Both events featured key fire-weather metrics that were unprecedented in the observational record that followed a sequence of climatic conditions that enhanced fine fuel abundance and fuel availability. The North Bay fires of October 2017 occurred coincident with strong downslope winds, with a majority of burned area occurring within the first 12 hours of ignition. By contrast, the southern California fires of December 2017 occurred during the longest Santa Ana wind event on record, resulting in the largest wildfire in California’s modern history. Both fire events occurred following an exceptionally wet winter that was preceded by a severe four-year drought. Fuels were further preconditioned by the warmest summer and autumn on record in northern and southern California, respectively. Finally, delayed onset of autumn precipitation allowed for critically low dead fuel moistures leading up to the wind events. Fire weather conditions were well forecast several days prior to the fire. However, the rarity of fire-weather conditions that occurred near populated regions, along with other societal factors such as limited evacuation protocols and limited wildfire preparedness in communities outside of the traditional wildland urban interface were key contributors to the widespread wildfire impacts.
Highlights
California’s fire history is littered with fast-moving, destructive wildfires adjacent to populated areas [1,2]
Through a case-study approach, we examined synoptic to meso-scale weather factors coincident to the events as well as climatic conditions antecedent to the events that resulted in exceptional surface fire weather conditions that led to rapid fire growth
Red Flag Warning criteria generally agree with Storm Prediction Center (SPC) critical fire weather criteria across the US, but there are differences in the specific criteria used by each National Weather Service (NWS) forecast office
Summary
California’s fire history is littered with fast-moving, destructive wildfires adjacent to populated areas [1,2]. The impacts of fire exclusion in shrublands, such as chaparral activity (e.g., burned area extent, number of large fires) over the past several decades [14] in part due ecosystems in California, are more mixed and generally weaker [1,11]. By seen a in noted increase in fire activity (e.g., and burned area extent, of large fires) over the past contrast, trends in fire activity have been more subdued in Mediterranean. Interannual most human-caused [18], as well as anthropogenic activities including land-use, fire policies, and climate variability does exhibit significant relationships to burned area extent in these regions [3,17,20,21].
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