Atmospheric Chemistry and Physics (Jan 2012)

Observation and modeling of the evolution of Texas power plant plumes

  • W. Zhou,
  • D. S. Cohan,
  • R. W. Pinder,
  • J. A. Neuman,
  • J. S. Holloway,
  • J. Peischl,
  • T. B. Ryerson,
  • J. B. Nowak,
  • F. Flocke,
  • W. G. Zheng

DOI
https://doi.org/10.5194/acp-12-455-2012
Journal volume & issue
Vol. 12, no. 1
pp. 455 – 468

Abstract

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During the second Texas Air Quality Study 2006 (TexAQS II), a full range of pollutants was measured by aircraft in eastern Texas during successive transects of power plant plumes (PPPs). A regional photochemical model is applied to simulate the physical and chemical evolution of the plumes. The observations reveal that SO<sub>2</sub> and NO<sub>y</sub> were rapidly removed from PPPs on a cloudy day but not on the cloud-free days, indicating efficient aqueous processing of these compounds in clouds. The model reasonably represents observed NO<sub>x</sub> oxidation and PAN formation in the plumes, but fails to capture the rapid loss of SO<sub>2</sub> (0.37 h<sup>−1</sup>) and NO<sub>y</sub> (0.24 h<sup>−1</sup>) in some plumes on the cloudy day. Adjustments to the cloud liquid water content (QC) and the default metal concentrations in the cloud module could explain some of the SO<sub>2</sub> loss. However, NO<sub>y</sub> in the model was insensitive to QC. These findings highlight cloud processing as a major challenge to atmospheric models. Model-based estimates of ozone production efficiency (OPE) in PPPs are 20–50 % lower than observation-based estimates for the cloudy day.