Surface dimming by the 2013 Rim Fire simulated by a sectional aerosol model

Pengfei Yu; Owen B Toon; Charles G Bardeen; Anthony Bucholtz; Karen H Rosenlof; Pablo E Saide; Arlindo Da Silva; Luke D Ziemba; Kenneth L Thornhill; Jose-Luis Jimenez; Pedro Campuzano-Jost; Joshua P Schwarz; Anne E Perring; Karl D Froyd; N L Wagner; Michael J Mills; Jeffrey S Reid

doi:10.1002/2015JD024702

Surface dimming by the 2013 Rim Fire simulated by a sectional aerosol model

J Geophys Res Atmos. 2016 Jun 27;121(12):7079-7087. doi: 10.1002/2015JD024702. Epub 2016 Jun 18.

Authors

Pengfei Yu¹, Owen B Toon², Charles G Bardeen³, Anthony Bucholtz⁴, Karen H Rosenlof⁵, Pablo E Saide⁶, Arlindo Da Silva⁷, Luke D Ziemba⁸, Kenneth L Thornhill⁹, Jose-Luis Jimenez¹⁰, Pedro Campuzano-Jost¹⁰, Joshua P Schwarz¹¹, Anne E Perring¹¹, Karl D Froyd¹¹, N L Wagner¹¹, Michael J Mills³, Jeffrey S Reid⁴

Affiliations

¹ Laboratory for Atmospheric and Space Physics University of Colorado Boulder Boulder Colorado USA; Department of Atmospheric and Oceanic Sciences University of Colorado Boulder Boulder Colorado USA; Cooperative Institute for Research in Environmental Science University of Colorado Boulder Boulder Colorado USA; Earth System Research Laboratory National Oceanic and Atmospheric Administration Boulder Colorado USA.
² Laboratory for Atmospheric and Space Physics University of Colorado Boulder Boulder Colorado USA; Department of Atmospheric and Oceanic Sciences University of Colorado Boulder Boulder Colorado USA.
³ Atmospheric Chemistry Observations and Modeling Laboratory National Center for Atmospheric Research Boulder Colorado USA.
⁴ Naval Research Laboratory Monterey California USA.
⁵ Earth System Research Laboratory National Oceanic and Atmospheric Administration Boulder Colorado USA.
⁶ Atmospheric Chemistry Observations and Modeling Laboratory National Center for Atmospheric Research Boulder Colorado USA; Center for Global and Regional Environmental Research The University of Iowa Iowa City Iowa USA.
⁷ NASA Goddard Space Flight Center Greenbelt Maryland USA.
⁸ NASA Langley Research Center Hampton Virginia USA.
⁹ Science Systems and Applications, Inc. Hampton Virginia USA.
¹⁰ Cooperative Institute for Research in Environmental Science University of Colorado Boulder Boulder Colorado USA; Department of Chemistry and Biochemistry University of Colorado Boulder Boulder Colorado USA.
¹¹ Cooperative Institute for Research in Environmental Science University of Colorado Boulder Boulder Colorado USA; Earth System Research Laboratory National Oceanic and Atmospheric Administration Boulder Colorado USA.

Abstract

The Rim Fire of 2013, the third largest area burned by fire recorded in California history, is simulated by a climate model coupled with a size-resolved aerosol model. Modeled aerosol mass, number, and particle size distribution are within variability of data obtained from multiple-airborne in situ measurements. Simulations suggest that Rim Fire smoke may block 4-6% of sunlight energy reaching the surface, with a dimming efficiency around 120-150 W m^-2 per unit aerosol optical depth in the midvisible at 13:00-15:00 local time. Underestimation of simulated smoke single scattering albedo at midvisible by 0.04 suggests that the model overestimates either the particle size or the absorption due to black carbon. This study shows that exceptional events like the 2013 Rim Fire can be simulated by a climate model with 1° resolution with overall good skill, although that resolution is still not sufficient to resolve the smoke peak near the source region.

Keywords: Rim Fire; radiative forcing; sectional aerosol model.