Long term changes in nitrogen oxides and volatile organic compounds in Toronto and the challenges facing local ozone control

Ground level ozone represents a significant air quality concern in Toronto, Canada, where the national 65 ppb 8-h standard is repeatedly exceeded during the summer. Here we present an analysis of nitrogen dioxide (NO 2), ozone (O 3), and volatile organic compound (VOC) data from federal and provinci...

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Bibliographic Details
Published in:Atmospheric environment (1994) 2009-07, Vol.43 (21), p.3407-3415
Main Authors: Geddes, Jeffrey A., Murphy, Jennifer G., Wang, Daniel K.
Format: Article
Language:English
Subjects:
Air pollution
Applied sciences
Atmospheric pollution
Atmospherics
Exact sciences and technology
Ground level ozone
Nitrogen dioxide
Nitrogen oxides
Organic compounds
Ozone
Pollution
Prevention and purification methods
Reduction
Summer
Toronto Canada
Urban areas
Volatile organic compounds
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Summary:Ground level ozone represents a significant air quality concern in Toronto, Canada, where the national 65 ppb 8-h standard is repeatedly exceeded during the summer. Here we present an analysis of nitrogen dioxide (NO 2), ozone (O 3), and volatile organic compound (VOC) data from federal and provincial governmental monitoring sites from 2000 to 2007. We show that summertime VOC reactivity and ambient concentrations of NO 2 have decreased over this period of time by up to 40% across Toronto and the surrounding region. This has not resulted in significant summertime ozone reductions, and in some urban areas, it appears to be increasing. We discuss the competing effects of decreased ozone titration leading to an increase in O 3, and decreased local ozone production, both caused by significant decreases in NO x concentrations. In addition, by using local meteorological data, we show that annual variability in summer ozone correlates strongly with maximum daily temperatures, and we explore the effect of atmospheric transport from the southwest which has a significant influence on early morning levels before local production begins. A mathematical model of instantaneous ozone production is presented which suggests that, given the observed decreases in NO x and VOC reactivity, we would not expect a significant change in local ozone production under photochemically relevant conditions. These results are discussed in the context of Toronto's recent commitment to cutting local smog-causing pollutants by 20% by 2012.
ISSN:1352-2310
1873-2844
DOI:10.1016/j.atmosenv.2009.03.053