Atmospheric Chemistry and Physics (Jan 2016)

Reactive nitrogen partitioning and its relationship to winter ozone events in Utah

  • R. J. Wild,
  • R. J. Wild,
  • P. M. Edwards,
  • P. M. Edwards,
  • P. M. Edwards,
  • T. S. Bates,
  • T. S. Bates,
  • R. C. Cohen,
  • J. A. de Gouw,
  • J. A. de Gouw,
  • W. P. Dubé,
  • W. P. Dubé,
  • J. B. Gilman,
  • J. B. Gilman,
  • J. Holloway,
  • J. Holloway,
  • J. Kercher,
  • A. R. Koss,
  • A. R. Koss,
  • L. Lee,
  • B. M. Lerner,
  • B. M. Lerner,
  • R. McLaren,
  • P. K. Quinn,
  • J. M. Roberts,
  • J. Stutz,
  • J. A. Thornton,
  • P. R. Veres,
  • P. R. Veres,
  • C. Warneke,
  • C. Warneke,
  • E. Williams,
  • C. J. Young,
  • C. J. Young,
  • C. J. Young,
  • B. Yuan,
  • B. Yuan,
  • K. J. Zarzana,
  • K. J. Zarzana,
  • S. S. Brown,
  • S. S. Brown

DOI
https://doi.org/10.5194/acp-16-573-2016
Journal volume & issue
Vol. 16
pp. 573 – 583

Abstract

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High wintertime ozone levels have been observed in the Uintah Basin, Utah, a sparsely populated rural region with intensive oil and gas operations. The reactive nitrogen budget plays an important role in tropospheric ozone formation. Measurements were taken during three field campaigns in the winters of 2012, 2013 and 2014, which experienced varying climatic conditions. Average concentrations of ozone and total reactive nitrogen were observed to be 2.5 times higher in 2013 than 2012, with 2014 an intermediate year in most respects. However, photochemically active NOx (NO + NO2) remained remarkably similar all three years. Nitric acid comprised roughly half of NOz ( ≡ NOy − NOx) in 2013, with nighttime nitric acid formation through heterogeneous uptake of N2O5 contributing approximately 6 times more than daytime formation. In 2012, N2O5 and ClNO2 were larger components of NOz relative to HNO3. The nighttime N2O5 lifetime between the high-ozone year 2013 and the low-ozone year 2012 is lower by a factor of 2.6, and much of this is due to higher aerosol surface area in the high-ozone year of 2013. A box-model simulation supports the importance of nighttime chemistry on the reactive nitrogen budget, showing a large sensitivity of NOx and ozone concentrations to nighttime processes.