Wintertime Overnight NOx Removal in a Southeastern United States Coal‐fired Power Plant Plume: A Model for Understanding Winter NOx Processing and its Implications

Autor: Marc N. Fiddler, William P. Dubé, Dorothy L. Fibiger, Kenneth C. Aikin, Glenn M. Wolfe, Paul J. Wooldridge, Nicola J. Blake, Rebecca S. Hornbrook, Ben H. Lee, Steven S. Brown, John S. Holloway, Ronald C. Cohen, C. J. Ebben, Andrew J. Weinheimer, Alan J. Hills, Felipe D. Lopez-Hilfiker, J. P. DiGangi, Solomon Bililign, Erin E. McDuffie, J. R. Green, Eric C. Apel, T. Sparks, Joel A. Thornton, Denise D. Montzka
Rok vydání: 2018
Předmět:
Zdroj: Journal of Geophysical Research: Atmospheres. 123:1412-1425
ISSN: 2169-8996
2169-897X
DOI: 10.1002/2017jd027768
Popis: Nitric oxide (NO) is emitted in large quantities from coal-burning power plants. During the day, the plumes from these sources are efficiently mixed into the boundary layer, while at night, they may remain concentrated due to limited vertical mixing during which they undergo horizontal fanning. At night, the degree to which NO is converted to HNO3 and therefore unable to participate in next-day ozone (O3) formation depends on the mixing rate of the plume, the composition of power plant emissions, and the composition of the background atmosphere. In this study, we use observed plume intercepts from the Wintertime INvestigation of Transport, Emissions and Reactivity (WINTER) campaign to test sensitivity of overnight NOx removal to the N2O5 loss rate constant, plume mixing rate, background O3, and background levels of volatile organic compounds using a 2-D box model of power plant plume transport and chemistry. The factor that exerted the greatest control over NOx removal was the loss rate constant of N2O5. At the lowest observed N2O5 loss rate constant, no other combination of conditions converts more than 10 percent of the initial NOx to HNO3. The other factors did not influence NOx removal to the same degree.
Databáze: OpenAIRE