NOy lifetimes and O3 production efficiencies in urban and power plant plumes: Analysis of field data

Abstract

In an effort to describe and characterize power plant plumes in the Nashville region, emissions from a small power plant (Gallatin) and a large power plant (Paradise) were examined using data obtained on the Department of Energy G‐1 airborne sampling platform. Observations made on July 3, 7, 15, 17, and 18, 1995, were compiled, and a kinetic analysis of the chemical evolution of the power plant plumes was performed. Analysis of the power plant plume data revealed a very active photochemistry, as had been determined previously for the urban plume. Ozone production efficiencies (OPE), defined as the number of molecules of O₃ formed per NO_x molecule consumed, were found to be 3 for Gallatin and 2 for Paradise. Lifetimes for NO_x (2.8 and 4.2 hours) and NO_y (7.0 and 7.7 hours) were determined for Gallatin and Paradise, respectively. These NO_x and NO_y lifetimes imply rapid loss of NO_z (NO_z is assumed to be primarily HNO₃). Lifetimes for NO_z are calculated to be 3 and 2.5 hours for Gallatin and Paradise, respectively. A sensitivity analysis indicates that the Gallatin NO_z lifetime could be as long as 5 hours, bringing it into agreement with the value determined for the Nashville urban plume. It is unlikely that the Paradise NO_z lifetime is as long as 4 hours. If NO_z loss is attributed to dry deposition, a 3 hour lifetime implies a deposition velocity greater than 10 cm s⁻¹, which is much faster than expected based on accepted theory. Possible reasons for this discrepancy are discussed.