Toward an integrated system for fire, smoke, and air quality simulations

TL;DR

This paper presents WRFSC, an integrated wildfire and smoke forecast system that directly predicts fire spread, emissions, and plume heights, showing good agreement with observations and potential for operational use.

Contribution

The study introduces WRFSC, a coupled system that integrates wildfire spread and atmospheric chemistry without needing plume-rise assumptions, improving fire-emission modeling.

Findings

Good agreement in fire spread and smoke transport predictions.

Accurate simulation of PM2.5 peak concentrations.

Plume-top height predictions closely match observations.

Abstract

In this study, we describe how WRF-Sfire is coupled with WRF-Chem to construct WRFSC, an integrated forecast system for wildfire and smoke prediction. The integrated forecast system has the advantage of not requiring a simple plume-rise model and assumptions about the size and heat release from the fire in order to determine fire emissions into the atmosphere. With WRF-Sfire, wildfire spread, plume and plume-top heights are predicted directly, at every WRF timestep, providing comprehensive meteorology and fire emissions to the chemical transport model WRF-Chem. Evaluation of WRFSC was based on comparisons between available observations to the results of two WRFSC simulations. The study found overall good agreement between forecasted and observed fire spread and smoke transport for the Witch-Guejito fire. Also the simulated PM2.5 (fine particulate matter) peak concentrations matched the observations. However, the NO and ozone levels were underestimated in the simulations and the peak concentrations were mistimed. Determining the terminal or plume-top height is one of the most important aspects of simulating wildfire plume transport, and the study found overall good agreement between simulated and observed plume-top heights, with some (10% or less) underestimation by the simulations. One of the most promising results of the study was the agreement between passive-tracer modeled plume-top heights for the Barker Canyon fire simulation and observations. This simulation took only 13h, with the first 24h forecast ready in almost 3h, making it a possible operational tool for providing emission profiles for external chemical transport models.