Wildfire Smoke Observations in the Western United States from the Airborne Wyoming Cloud Lidar during the BB-FLUX Project. Part I: Data Description and Methodology

Abstract During the summer of 2018, the upward-pointing Wyoming Cloud Lidar (WCL) was deployed on board the University of Wyoming King Air (UWKA) research aircraft for the Biomass Burning Flux Measurements of Trace Gases and Aerosols (BB-FLUX) field campaign. This paper describes the generation of c...

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Published inJournal of atmospheric and oceanic technology Vol. 39; no. 5; pp. 545 - 558
Main Authors Deng, Min, Wang, Zhien, Volkamer, Rainer, Snider, Jefferson R., Oolman, Larry, Plummer, David M., Kille, Natalie, Zarzana, Kyle J., Lee, Christopher F., Campos, Teresa, Mahon, Nicholas Ryan, Glover, Brent, Burkhart, Matthew D., Morgan, Austin
Format Journal Article
LanguageEnglish
Published Boston American Meteorological Society 01.05.2022
Subjects
Aerosol concentrations
Aerosol extinction
Aerosol particles
Aerosols
Airborne sensing
Backscatter
Backscattering
Biomass burning
Burning
Carbon aerosols
Carbon monoxide
Coefficients
Correlation coefficient
Correlation coefficients
Depolarization
Flight
Flight time
Fluctuations
Gases
Lidar
Plumes
Research aircraft
Smoke
Smoke plumes
Solar occultation
Trace gases
Wildfires
United States > US
Wyoming
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Summary:Abstract During the summer of 2018, the upward-pointing Wyoming Cloud Lidar (WCL) was deployed on board the University of Wyoming King Air (UWKA) research aircraft for the Biomass Burning Flux Measurements of Trace Gases and Aerosols (BB-FLUX) field campaign. This paper describes the generation of calibrated attenuated backscatter coefficients and aerosol extinction coefficients from the WCL measurements. The retrieved aerosol extinction coefficients at the flight level strongly correlate (correlation coefficient, rr > 0.8) with in situ aerosol concentration and carbon monoxide (CO) concentration, providing a first-order estimate for converting WCL extinction coefficients into vertically resolved CO and aerosol concentration within wildfire smoke plumes. The integrated CO column concentrations from the WCL data in nonextinguished profiles also correlate (rr = 0.7) with column measurements by the University of Colorado Airborne Solar Occultation Flux instrument, indicating the validity of WCL-derived extinction coefficients. During BB-FLUX, the UWKA sampled smoke plumes from more than 20 wildfires during 35 flights over the western United States. Seventy percent of flight time was spent below 3 km above ground level (AGL) altitude, although the UWKA ascended up to 6 km AGL to sample the top of some deep smoke plumes. The upward-pointing WCL observed a nearly equal amount of thin and dense smoke below 2 km and above 5 km due to the flight purpose of targeted fresh fire smoke. Between 2 and 5 km, where most of the wildfire smoke resided, the WCL observed slightly more thin smoke than dense smoke due to smoke spreading. Extinction coefficients in dense smoke were 2–10 times stronger, and dense smoke tended to have larger depolarization ratio, associated with irregular aerosol particles.
ISSN:0739-0572
1520-0426
DOI:10.1175/JTECH-D-21-0092.1