Biophysical Mechanistic Modelling Quantifies the Effects of Plant Traits on Fire Severity: Species, Not Surface Fuel Loads, Determine Flame Dimensions in Eucalypt Forests

The influence of plant traits on forest fire behaviour has evolutionary, ecological and management implications, but is poorly understood and frequently discounted. We use a process model to quantify that influence and provide validation in a diverse range of eucalypt forests burnt under varying con...

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Veröffentlicht in:	PloS one 2016-08, Vol.11 (8), p.e0160715-e0160715
Hauptverfasser:	Zylstra, Philip, Bradstock, Ross A, Bedward, Michael, Penman, Trent D, Doherty, Michael D, Weber, Rodney O, Gill, A Malcolm, Cary, Geoffrey J
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Sprache:	eng
Schlagworte:	Analysis Australia Biodiversity Biology and Life Sciences Biophysical Phenomena Disasters Earth Sciences Ecological effects Ecology and Environmental Sciences Ecosystems Engineering and Technology Environment Environmental aspects Eucalypta Fires Forest fires Forest management Forests Fuels Hot Temperature Influence Mathematical models Model accuracy Models, Biological Moisture content Morphology Physical Sciences Plant evolution Plant Leaves - metabolism Plant species Plants (botany) Plants - metabolism Species
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creator	Zylstra, Philip Bradstock, Ross A Bedward, Michael Penman, Trent D Doherty, Michael D Weber, Rodney O Gill, A Malcolm Cary, Geoffrey J
description	The influence of plant traits on forest fire behaviour has evolutionary, ecological and management implications, but is poorly understood and frequently discounted. We use a process model to quantify that influence and provide validation in a diverse range of eucalypt forests burnt under varying conditions. Measured height of consumption was compared to heights predicted using a surface fuel fire behaviour model, then key aspects of our model were sequentially added to this with and without species-specific information. Our fully specified model had a mean absolute error 3.8 times smaller than the otherwise identical surface fuel model (p < 0.01), and correctly predicted the height of larger (≥1 m) flames 12 times more often (p < 0.001). We conclude that the primary endogenous drivers of fire severity are the species of plants present rather than the surface fuel load, and demonstrate the accuracy and versatility of the model for quantifying this.
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subjects	Analysis Australia Biodiversity Biology and Life Sciences Biophysical Phenomena Disasters Earth Sciences Ecological effects Ecology and Environmental Sciences Ecosystems Engineering and Technology Environment Environmental aspects Eucalypta Fires Forest fires Forest management Forests Fuels Hot Temperature Influence Mathematical models Model accuracy Models, Biological Moisture content Morphology Physical Sciences Plant evolution Plant Leaves - metabolism Plant species Plants (botany) Plants - metabolism Species
title	Biophysical Mechanistic Modelling Quantifies the Effects of Plant Traits on Fire Severity: Species, Not Surface Fuel Loads, Determine Flame Dimensions in Eucalypt Forests
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