Abstract

Heating from wildfires adds buoyancy to the overlying air, often producing plumes that vertically distribute fire emissions throughout the atmospheric column over the fire. The height of the rising wildfire plume is a complex function of the size of the wildfire, fire heat flux, plume geometry, and atmospheric conditions, which can make simulating plume rises difficult with coarser-scale atmospheric models. To determine the altitude of fire emission injection, several plume rise parameterizations have been developed in an effort estimate the height of the wildfire plume rise. Previous work has indicated the performance of these plume rise parameterizations has generally been mixed when validated against satellite observations. However, it is often difficult to evaluate the performance of plume rise parameterizations due to the significant uncertainties associated with fire input parameters such as fire heat fluxes and area. In order to reduce the uncertainties of fire input parameters, we applied an atmospheric modeling framework with different plume rise parameterizations to a well constrained prescribed burn, as part of the RxCADRE field experiment. Initial results found that the model was unable to reasonably replicate downwind smoke for cases when fire emissions were emitted at the surface and released at the top of the plume. However, when fire emissions were distributed below the plume top following a Gaussian distribution, model results were significantly improved.

Highlights

  • Research has shown that fires are responsible for emitting a significant amount of aerosols (PM2.5 and PM10 ) and trace gases (CO, CO2, and CH4 ) into Earth’s atmosphere [1]

  • Significant uncertainties exist within atmospheric and chemical transport models in regards to how fire emissions should be vertically distributed as a result of the wildfire plume rise

  • Fire area and heat flux are challenging parameters to measure, resulting in large errors that often propagate into plume rise parameterizations [11]

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Summary

Introduction

Research has shown that fires are responsible for emitting a significant amount of aerosols (PM2.5 and PM10 ) and trace gases (CO, CO2 , and CH4 ) into Earth’s atmosphere [1]. CO2 and CH4 are greenhouse gases responsible for climate change [2] while CO, PM2.5 , and PM10 are criteria pollutants regulated by the U.S Environmental Protection Agency (EPA). Aerosols from wildfires can have significant impacts on air quality and human health. Smoke from wildfires can often have local and regional impacts on air quality and visibility. Impacts from wildfire smoke are projected to worsen through the end the 21st century as the number of large fires increases as a result of climate change [8,9,10]

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