Atmospheric Chemistry and Physics (Aug 2020)

Glyoxal's impact on dry ammonium salts: fast and reversible surface aerosol browning

  • D. O. De Haan,
  • L. N. Hawkins,
  • K. Jansen,
  • H. G. Welsh,
  • R. Pednekar,
  • A. de Loera,
  • N. G. Jimenez,
  • M. A. Tolbert,
  • M. Cazaunau,
  • A. Gratien,
  • A. Bergé,
  • E. Pangui,
  • P. Formenti,
  • J.-F. Doussin

DOI
https://doi.org/10.5194/acp-20-9581-2020
Journal volume & issue
Vol. 20
pp. 9581 – 9590

Abstract

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Alpha-dicarbonyl compounds are believed to form brown carbon in the atmosphere via reactions with ammonium sulfate (AS) in cloud droplets and aqueous aerosol particles. In this work, brown carbon formation in AS and other aerosol particles was quantified as a function of relative humidity (RH) during exposure to gas-phase glyoxal (GX) in chamber experiments. Under dry conditions (RH < 5 %), solid AS, AS–glycine, and methylammonium sulfate (MeAS) aerosol particles brown within minutes upon exposure to GX, while sodium sulfate particles do not. When GX concentrations decline, browning goes away, demonstrating that this dry browning process is reversible. Declines in aerosol albedo are found to be a function of [GX]2 and are consistent between AS and AS–glycine aerosol. Dry methylammonium sulfate aerosol browns 4 times more than dry AS aerosol, but deliquesced AS aerosol browns much less than dry AS aerosol. Optical measurements at 405, 450, and 530 nm provide an estimated Ångstrom absorbance coefficient of -16±4. This coefficient and the empirical relationship between GX and albedo are used to estimate an upper limit to global radiative forcing by brown carbon formed by 70 ppt GX reacting with AS (+7.6×10-5 W m−2). This quantity is < 1 % of the total radiative forcing by secondary brown carbon but occurs almost entirely in the ultraviolet range.