Fire, Fuel, and Climate Interactions in Temperate Climates
Stephanie K. Kampf,
Camille S. Stevens‐Rumann,
Leónia Nunes,
Ana Catarina Sequeira,
Francisco Castro Rego,
Cristina Fernández,
Ana Hernández‐Duarte,
Clara E. Mosso,
Jean Pierre Francois,
Alejandro Miranda
Affiliations
Stephanie K. Kampf
Department of Ecosystem Science and Sustainability Colorado State University Fort Collins CO USA
Camille S. Stevens‐Rumann
Department of Forest and Rangeland Stewardship Colorado Forest Restoration Institute Colorado State University Fort Collins CO USA
Leónia Nunes
Centre for Applied Ecology “Professor Baeta Neves” (CEABN) InBIO School of Agriculture University of Lisbon Lisbon Portugal
Ana Catarina Sequeira
Centre for Applied Ecology “Professor Baeta Neves” (CEABN) InBIO School of Agriculture University of Lisbon Lisbon Portugal
Francisco Castro Rego
Centre for Applied Ecology “Professor Baeta Neves” (CEABN) InBIO School of Agriculture University of Lisbon Lisbon Portugal
Cristina Fernández
Misión Biológica de Galicia National Spanish Research Council (MBG‐CSIC) Pontevedra Spain
Ana Hernández‐Duarte
Programa de Doctorado Interdisciplinario en Ciencias Ambientales Universidad de Playa Ancha Valparaíso Chile
Clara E. Mosso
Department of Ecosystem Science and Sustainability Graduate Degree Program in Ecology Colorado State University Fort Collins CO USA
Jean Pierre Francois
Laboratorio de Geografía Ambiental y Palinología (Lab GAP‐UPLA) Departamento de Ciencias y Geografía Facultad de Ciencias Naturales y Exactas HUB Ambiental UPLA Universidad de Playa Ancha Valparaiso Chile
Alejandro Miranda
Departamento de Ciencias Forestales Universidad de La Frontera Temuco Chile
Abstract Temperate regions around the world are experiencing longer fire weather seasons, yet trends in burned area have been inconsistent between regions. Reasons for differences in fire patterns can be difficult to determine due to variable vegetation types, land use patterns, fuel conditions, and human influences on fire ignition and suppression. This study compares burned areas to climate and fuel conditions in three temperate regions: the desert, shrub, and forest ecoregions of western North America, west‐central Europe, and southwestern South America. In each region the mean annual aridity index (AI, precipitation over potential evapotranspiration) spans arid to humid climates. We examined how the fraction of area burned from 2001 to 2021 varied with mean annual AI, mean aboveground biomass, and land cover type distributions. All three regions had low fractions of area burned for the driest climate zones (AI 1.5), a sign of climate limitation to burned area. Of the three regions, western North America had the highest burned area, fraction of area burned, and fire sizes. Fragmentation of vegetation patches by the high Andes Mountains in southwestern South America and by intensive land use changes in west‐central Europe likely limited fire sizes. All three regions are at risk for future wildfires, particularly in areas where fire is currently climate limited.
