Description of a coupled atmosphere–fire model
Terry L. Clark A C , Janice Coen A and Don Latham BA National Center for Atmospheric Research, PO Box 3000, Boulder, CO 80307, USA.
B USDA Forest Service, Fire Sciences Laboratory, Rocky Mountain Research Station, PO Box 8089, Missoula, MT 59802, USA. Email: djl@montana.com
C Corresponding author. Present address: University of British Columbia, Department of Earth and Ocean Sciences, 6339 Stores Road, Vancouver, V6T 1Z4, Canada. Telephone: +1 604 822 0278; fax: +1 604 822 6088; email:tclark@eos.ubc.ca
International Journal of Wildland Fire 13(1) 49-63 https://doi.org/10.1071/WF03043
Submitted: 29 April 2003 Accepted: 6 May 2003 Published: 8 April 2004
Abstract
This paper describes a coupled fire–atmosphere model that uses a sophisticated high-resolution non-hydrostatic numerical mesoscale model to predict the local winds which are then used as input to the prediction of fire spread. The heat and moisture fluxes from the fire are then fed back to the dynamics, allowing the fire to influence its own mesoscale winds that in turn affect the fire behavior.
This model is viewed as a research model and as such requires a fireline propagation scheme that systematically converges with increasing spatial and temporal resolution. To achieve this, a local contour advection scheme was developed to track the fireline using four tracer particles per fuel cell, which define the area of burning fuel. Using the dynamically predicted winds along with the terrain slope and fuel characteristics, algorithms from the BEHAVE system are used to predict the spread rates. A mass loss rate calculation, based on results of the BURNUP fuel burnout model, is used to treat heat exchange between the fire and atmosphere.
Tests were conducted with the uncoupled model to test the fire-spread algorithm under specified wind conditions for both spot and line fires. Using tall grass and chaparral, line fires were simulated employing the full fire–atmosphere coupling. Results from two of these experiments show the effects of fire propagation over a small hill. As with previous coupled experiments, the present results show a number of features common to real fires. For example, we show how the well-recognized elliptical fireline shape is a direct result of fire–atmosphere interactions that produce the ‘heading’, ‘flanking’, and ‘backing’ regions of a wind-driven fire with their expected behavior. And, we see how perturbations upon this shape sometimes amplify to become fire whirls along the flanks, which are transported to the head of the fire where they may interact to produce erratic fire behavior.
Acknowledgements
We thank Francis Fujioka of the Riverside Fire Laboratory, USDA Forest Service, for his partial support of the work carried out in this paper. This work was supported in part by funds provided by the Rocky Mountain Research Station, USDA Forest Service (Research Work Unit RMRS-4401) and the Riverside Fire Laboratory, USDA Forest Service (Research Work Unit PSW-4401).
Albini FA (1993) Dynamics and modeling of vegetation fires: observations. In
Albini FA (1994) PROGRAM BURNUP: A simulation model of the burning of large woody natural fuels. Final report on Research Grant INT-92754-GR by USFS to Montana State University, Mechanical Engineering Department
Albini FA, Brown JK, Reinhardt ED , Ottmar RD (1995) Calibration of a large fuel burnout model. International Journal of Wildland Fire 5, 173–192.
Albini FA , Reinhardt ED (1995) Modeling ignition and burning rate of large woody natural fuels. International Journal of Wildland Fire 5, 81–91.
Anderson DH, Catchpole EA, de Mestre NJ , Parkes T (1982) Modelling the spread of grass fires. Journal of the Australian Mathematical Society B 23, 451–466.
Andrews PL (1986) BEHAVE: Fire behavior prediction and fuel modeling system–BURN subsystem Part 1. USDA Forest Service, Intermountain Research Station General Technical Report INT-194 (Ogden, UT) 130 pp.
Ball GL , Geurtin DP (1992) Improved fire growth modeling. International Journal of Wildland Fire 2(2), 47–54.
Clark TL (1977) A small-scale dynamic model using a terrain-following coordinate transformation. Journal of Computational Physics 24, 186–215.
Clark TL (1979) Numerical simulations with a three-dimensional cloud model: lateral boundary condition experiments and multicellular severe storm simulations. Journal of Atmospheric Sciences 36, 2192–2215.
Clark TL , Farley WR (1984) Severe downslope windstorm calculations in two and three spatial dimensions using anelastic interactive grid nesting: a possible mechanism for gustiness. Journal of Atmospheric Sciences 41, 329–350.
| Crossref | GoogleScholarGoogle Scholar |
Clark TL , Hall WD (1996) On the design of smooth, conservative vertical grids for interactive grid nesting with stretching. Journal of Applied Meteorology 35, 1040–1046.
| Crossref | GoogleScholarGoogle Scholar |
Clark TL, Jenkins MA, Coen J , Packham D (1996a) A coupled atmospheric–fire model: convective feedback on fire line dynamics. Journal of Applied Meteorology 35, 875–901.
| Crossref | GoogleScholarGoogle Scholar |
Clark TL, Jenkins MA, Coen J , Packham D (1996b) A coupled atmospheric–fire model: convective Froude number and dynamic fingering. International Journal of Wildland Fire 6, 177–190.
Finney M (1998) FARSITE: Fire Area Simulator–model development and evaluation. USDA Forest Service, Rocky Mountain Research Station Research Paper RMRS-RP-4 47 pp.
Linn RL (1997). A transport model for prediction of wildfire behavior. Los Alamos National Laboratory thesis LA-13334-T (New Mexico State University) 195 pp.
Luke RH, McArthur AG (1978) Bushfires in Australia (Australian Government Publishing Service: Canberra) 359 pp.
Richards GD (1995) A general mathematical framework for modelling two-dimensional wildland fire spread. International Journal of Wildland Fire 5, 63–71.
Richards GD , Bryce RW (1995) A computer algorithm for simulating the spread of wildland fire perimeters for heterogeneous fuel and meteorological conditions. International Journal of Wildland Fire 5, 73–79.
Richards GD (1994) The properties of elliptical wildfire growth for time dependent fuel and meteorological conditions. Combustion Science and Technology 95, 357–383.
Rothermel RC (1972) A mathematical model for predicting fire spread in wildland fuels. USDA Forest Service, Intermountain Research Station Research Paper INT-115 (Ogden, UT) 41 pp.
Vasconcelos MJ , Geurtin GP (1992) FIREMAP–simulation of fire growth with a geographic information system. International Journal of Wildland Fire 2(2), 87–96.
