Fire-modified meteorology in a coupled fire-atmosphere model
Date
2015
Authors
Peace, M.
Mattner, T.
Mills, G.
Kepert, J.
Mccaw, L.
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Journal article
Citation
Journal of Applied Meteorology and Climatology, 2015; 54(3):704-720
Statement of Responsibility
Mika Peace, Trent Mattner, Graham Mills, Jeffrey Kepert, Lachlan McCaw
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Abstract
The coupled fire-atmosphere model consisting of the Weather and Forecasting (WRF) Model coupled with the fire-spread model (SFIRE) module has been used to simulate a bushfire at D’Estrees Bay on Kangaroo Island, South Australia, in December 2007. Initial conditions for the simulations were provided by two global analyses: the GFS operational analysis and ERA-Interim. For each NWP initialization, the simulations were run with and without feedback from the fire to the atmospheric model. The focus of this study was examining how the energy fluxes from the simulated fire modified the local meteorological environment. With feedback enabled, the propagation speed of the sea-breeze frontal line was faster and vertical motion in the frontal zone was enhanced. For one of the initial conditions with feedback on, a vortex developed adjacent to the head fire and remained present for over 5 h of simulation time. The vortex was not present without fire-atmosphere feedback. The results show that the energy fluxes released by a fire can effect significant changes on the surrounding mesoscale atmosphere. This has implications for the appropriate use of weather parameters extracted from NWP and used in prediction for fire operations. These meteorological modifications also have implications for anticipating likely fire behavior.
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© 2015 American Meteorological Society