A coupled atmosphere-fire model: Role of the convective froude number and dynamic fingering at the fireline

Terry L. Clark; Mary Ann Jenkins; Janice L. Coen; David R. Packham

doi:10.1071/WF9960177

A coupled atmosphere-fire model: Role of the convective froude number and dynamic fingering at the fireline

Terry L. Clark, Mary Ann Jenkins, Janice L. Coen, David R. Packham

Dynamical and Physical Meteorology

Research output: Contribution to journal › Article › peer-review

111 Scopus citations

Abstract

A numerical atmospheric model is coupled with a simple dry eucalyptus forest fire model to create a wildfire simulation model. This is used to show how certain atmospheric conditions can lead to commonly observed forest fire behavior. Using short line fires, simulations show that with moderate winds, the fire line interacts with the updraft ahead of it causing the fire line to curve forward into a conical shape. Other experiments show that when ambient winds change with height, a pair of rotating updrafts at the curved fire front can touch down within the fire and break up the fire line. We also demonstrate 'dynamic fingering', in which the rotating columns near the fire front intensify to tornado strength and can result in rapid and strong increases in the fire spread rate.

Original language	English
Pages (from-to)	177-190
Number of pages	14
Journal	International Journal of Wildland Fire
Volume	6
Issue number	4
DOIs	https://doi.org/10.1071/WF9960177
State	Published - Dec 1996

Keywords

Atmospheric model
Dynamic fingering
Fire dynamics

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10.1071/WF9960177

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@article{7598dc9e968e4c1abc5882255466ec6b,

title = "A coupled atmosphere-fire model: Role of the convective froude number and dynamic fingering at the fireline",

abstract = "A numerical atmospheric model is coupled with a simple dry eucalyptus forest fire model to create a wildfire simulation model. This is used to show how certain atmospheric conditions can lead to commonly observed forest fire behavior. Using short line fires, simulations show that with moderate winds, the fire line interacts with the updraft ahead of it causing the fire line to curve forward into a conical shape. Other experiments show that when ambient winds change with height, a pair of rotating updrafts at the curved fire front can touch down within the fire and break up the fire line. We also demonstrate 'dynamic fingering', in which the rotating columns near the fire front intensify to tornado strength and can result in rapid and strong increases in the fire spread rate.",

keywords = "Atmospheric model, Dynamic fingering, Fire dynamics",

author = "Clark, \{Terry L.\} and Jenkins, \{Mary Ann\} and Coen, \{Janice L.\} and Packham, \{David R.\}",

year = "1996",

month = dec,

doi = "10.1071/WF9960177",

language = "English",

volume = "6",

pages = "177--190",

journal = "International Journal of Wildland Fire",

issn = "1049-8001",

publisher = "CSIRO Publishing ",

number = "4",

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TY - JOUR

T1 - A coupled atmosphere-fire model

T2 - Role of the convective froude number and dynamic fingering at the fireline

AU - Clark, Terry L.

AU - Jenkins, Mary Ann

AU - Coen, Janice L.

AU - Packham, David R.

PY - 1996/12

Y1 - 1996/12

N2 - A numerical atmospheric model is coupled with a simple dry eucalyptus forest fire model to create a wildfire simulation model. This is used to show how certain atmospheric conditions can lead to commonly observed forest fire behavior. Using short line fires, simulations show that with moderate winds, the fire line interacts with the updraft ahead of it causing the fire line to curve forward into a conical shape. Other experiments show that when ambient winds change with height, a pair of rotating updrafts at the curved fire front can touch down within the fire and break up the fire line. We also demonstrate 'dynamic fingering', in which the rotating columns near the fire front intensify to tornado strength and can result in rapid and strong increases in the fire spread rate.

AB - A numerical atmospheric model is coupled with a simple dry eucalyptus forest fire model to create a wildfire simulation model. This is used to show how certain atmospheric conditions can lead to commonly observed forest fire behavior. Using short line fires, simulations show that with moderate winds, the fire line interacts with the updraft ahead of it causing the fire line to curve forward into a conical shape. Other experiments show that when ambient winds change with height, a pair of rotating updrafts at the curved fire front can touch down within the fire and break up the fire line. We also demonstrate 'dynamic fingering', in which the rotating columns near the fire front intensify to tornado strength and can result in rapid and strong increases in the fire spread rate.

KW - Atmospheric model

KW - Dynamic fingering

KW - Fire dynamics

UR - https://www.scopus.com/pages/publications/0040121326

U2 - 10.1071/WF9960177

DO - 10.1071/WF9960177

M3 - Article

AN - SCOPUS:0040121326

SN - 1049-8001

VL - 6

SP - 177

EP - 190

JO - International Journal of Wildland Fire

JF - International Journal of Wildland Fire

IS - 4

ER -

A coupled atmosphere-fire model: Role of the convective froude number and dynamic fingering at the fireline

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Keywords

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