Modeling actinic flux and photolysis frequencies in dense biomass burning plumes

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This work is licensed under a Creative Commons Attribution 4.0 International License.

Authors

Jan-Lukas Tirpitz, UCLA, Los Angeles
Santo Fedele Colosimo, UCLA, Los Angeles
Nathaniel Brockway, University of Alaska
Robert Spurr, RT Solutions Inc
Matt Christi
Samuel Hall, National Center for Atmospheric Research
Kirk Ullmann, National Center for Atmospheric Research
Johnathan Hair, National Aeronautics and Space Administration
Taylor Shingler, National Aeronautics and Space Administration
Rodney Weber, Georgia Institute of Technology
Jack E. Dibb, University of New Hampshire, DurhamFollow
Richard Moore, Langley Research Center
Elizabeth Wiggins, Langley Research Center
Vijay Natraj, California Institute of Technology
Nicolas Theys, Royal Belgian Institute for Space Aeronomy
Jochen Stutz, UCLA, Los Angeles

Abstract

Biomass burning (BB) affects air quality and climate by releasing large quantities of gaseous and particulate pollutants into the atmosphere. Photochemical processing during daylight transforms these emissions, influencing their overall environmental impact. Accurately quantifying the photochemical drivers, namely actinic flux and photolysis frequencies, is crucial to constraining this chemistry. However, the complex radiative transfer within BB plumes presents a significant challenge for both direct observations and numerical models.

This study introduces an expanded version of the 1D VLIDORT-QS radiative transfer (RT) model, named VLIDORT for photochemistry (VPC). VPC is designed for photochemical and remote sensing applications, particularly in BB plumes and other complex scenarios. To validate VPC and investigate photochemical conditions within BB plumes, the model was used to simulate spatial distributions of actinic fluxes and photolysis frequencies for the Shady wildfire (Idaho, US, 2019) based on plume composition data from the NOAA/NASA FIREX-AQ (Fire Influence on Regional to Global Environments and Air Quality) campaign. Comparison between modeling results and observations by the CAFS (charged-coupled device actinic flux spectroradiometer) yields a modeling accuracy of 10 %–20 %. Systematic biases between the model and observations are within 2 %, indicating that the uncertainties are most likely due to variability in the input data caused by the inhomogeneity of the plume as well as 3D RT effects not captured in the model. Random uncertainties are largest in the ultraviolet (UV) spectral range, where they are dominated by uncertainties in the plume particle size distribution and brown carbon (BrC) absorptive properties. The modeled actinic fluxes show a decrease from the plume top to the bottom of the plume with a strong spectral dependence caused by BrC absorption, which darkens the plume towards shorter wavelengths. In the visible (Vis) spectral range, actinic fluxes above the plume are enhanced by up to 60 %. In contrast, in the UV, actinic fluxes above the plume are not affected or even reduced by up to 10 %. Strong reductions exceeding an order of magnitude in and below the plume occur for both spectral ranges but are more pronounced in the UV.

Department

Earth Systems Research Center

Publication Date

2-14-2025

Journal Title

Atmospheric Chemistry and Physics

Publisher

EGU

Digital Object Identifier (DOI)

https://dx.doi.org/10.5194/acp-25-1989-2025

Document Type

Article

Recommended Citation

Tirpitz, J.-L., S. F. Colosimo, N. Brockway, R. Spurr, M. Christi, S. Hall, K. Ulmann, J. Hair, T. Shingler, R. Weber, J. Dibb, R. Moore, E. Wiggins, V. Natraj, N. Theys, and J. Stutz (2025), Modeling actinic flux and photolysis frequencies in dense biomass burning plumes, Atmospheric Chemistry and Physics, 25, 1989-2015, https:doi.org/10.5194/acp-25-1989-2025.

Rights

© Author(s) 2025.

Comments

This is an open access article published by EGU in Atmospheric Chemistry and Physics in 2025, available online: https://dx.doi.org/10.5194/acp-25-1989-2025