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Environ Pollut


Title:Large eddy simulation of reactive pollutants in a deep urban street canyon: Coupling dynamics with O(3)-NO(x)-VOC chemistry
Author(s):Zhong J; Cai XM; Bloss WJ;
Address:"School of Geography, Earth & Environmental Sciences, University of Birmingham, Edgbaston, Birmingham, B15 2TT, UK. School of Geography, Earth & Environmental Sciences, University of Birmingham, Edgbaston, Birmingham, B15 2TT, UK. Electronic address: x.cai@bham.ac.uk"
Journal Title:Environ Pollut
Year:2017
Volume:20170212
Issue:
Page Number:171 - 184
DOI: 10.1016/j.envpol.2017.01.076
ISSN/ISBN:1873-6424 (Electronic) 0269-7491 (Linking)
Abstract:"A large eddy simulation (LES) model coupled with O(3)-NO(x)-VOC chemistry is implemented to simulate the coupled effects of emissions, mixing and chemical pre-processing within an idealised deep (aspect ratio = 2) urban street canyon under a weak wind condition. Reactive pollutants exhibit significant spatial variations in the presence of two vertically aligned unsteady vortices formed in the canyon. Comparison of the LES results from two chemical schemes (simple NO(x)-O(3) chemistry and a more comprehensive Reduced Chemical Scheme (RCS) chemical mechanism) shows that the concentrations of NO(2) and O(x) inside the street canyon are enhanced by approximately 30-40% via OH/HO(2) chemistry. NO, NO(x), O(3), OH and HO(2) are chemically consumed, while NO(2) and O(x) (total oxidant) are chemically produced within the canyon environment. Within-canyon pre-processing increases oxidant fluxes from the canyon to the overlying boundary layer, and this effect is greater for deeper street canyons (as found in many traditional European urban centres) than shallower (lower aspect ratio) streets. There is clear evidence of distinct behaviours for emitted chemical species and entrained chemical species, and positive (or negative) values of intensities of segregations are found between pairs of species with similar (or opposite) behaviour. The simplified two-box model underestimated NO and O(3) levels, but overestimated NO(2) levels for both the lower and upper canyon compared with the more realistic LES-chemistry model. This suggests that the segregation effect due to incomplete mixing reduces the chemical conversion rate of NO to NO(2). This study reveals the impacts of nonlinear O(3)-NO(x)-VOC photochemical processes in the incomplete mixing environment and provides a better understanding of the pre-processing of emissions within canyons, prior to their release to the urban boundary layer, through the coupling of street canyon dynamics and chemistry"
Keywords:"Air Pollutants/*analysis/*chemistry *Cities *Computer Simulation Environmental Pollution/analysis Models, Theoretical Nitric Oxide/analysis/chemistry Nitrogen Dioxide/analysis/*chemistry Oxygen/analysis/*chemistry Photochemical Processes Volatile Organic;"
Notes:"MedlineZhong, Jian Cai, Xiao-Ming Bloss, William James eng England 2017/02/17 Environ Pollut. 2017 May; 224:171-184. doi: 10.1016/j.envpol.2017.01.076. Epub 2017 Feb 12"

 
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