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Published December 4, 2018 | Supplemental Material
Journal Article Open

Constraints on aerosol nitrate photolysis as a potential source of HONO and NO_x

Romer, Paul S. ORCID icon
Wooldridge, Paul J. ORCID icon
Crounse, John D. ORCID icon
Kim, Michelle J. ORCID icon
Wennberg, Paul O. ORCID icon
Dibb, Jack E. ORCID icon
Scheuer, Eric ORCID icon
Blake, Donald R. ORCID icon
Meinardi, Simone ORCID icon
Brosius, Alexandra L. ORCID icon
Thames, Alexander B.
Miller, David O.
Brune, William H. ORCID icon
Hall, Samuel R. ORCID icon
Ryerson, Thomas B. ORCID icon
Cohen, Ronald C. ORCID icon

Abstract

The concentration of nitrogen oxides (NO_x) plays a central role in controlling air quality. On a global scale, the primary sink of NO_x is oxidation to form HNO_3. Gas-phase HNO_3 photolyses slowly with a lifetime in the troposphere of 10 days or more. However, several recent studies examining HONO chemistry have proposed that particle-phase HNO_3 undergoes photolysis 10–300 times more rapidly than gas-phase HNO_3. We present here constraints on the rate of particle-phase HNO_3 photolysis based on observations of NO_x and HNO_3 collected over the Yellow Sea during the KORUS-AQ study in summer 2016. The fastest proposed photolysis rates are inconsistent with the observed NO_x to HNO_3 ratios. Negligible to moderate enhancements of the HNO_3 photolysis rate in particles, 1–30 times faster than in the gas phase, are most consistent with the observations. Small or moderate enhancement of particle-phase HNO_3 photolysis would not significantly affect the HNO_3 budget but could help explain observations of HONO and NO_x in highly aged air.

Additional Information

© 2018 American Chemical Society. Received: July 13, 2018; Revised: October 22, 2018; Accepted: November 8, 2018; Published: November 8, 2018. We thank NASA for support via NNX15AT85G (Berkeley), NNX15AT97G and NNX14AP46G (Caltech), NNX14AP46G (UNH), and NNX16AD96G (to C.K.). M.J.K. was supported by NSF AGS Award No. 1524860. Methanol and acetaldehyde measurements were supported by the Austrian Federal Ministry for Transport, Innovation and Technology (bmvit) through the Austrian Research Promotion Agency (FFG). The authors thank Alan Fried for the formaldehyde measurements, Armin Wisthaler for the methanol and acetaldehyde measurements, Christoph Knote for the FLEXPART model results, Glenn Diskin for the CH4 and CO measurements, and Andrew Weinheimer and Denise Montzka for NO measurements. We thank Tamara Sparks and Alex Teng for assistance in the field, the ground and flight crew of the DC-8, and the KORUS-AQ science team. The authors declare no competing financial interest.

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