Abstract
Abstract. In spring 2002, an atmospheric measurement site was established at the peak of Whistler Mountain in British Columbia, Canada to measure trace gases, particle chemistry and physics, and meteorology. This paper uses continuous measurements from March 2002 to December 2006 to investigate the influence of trans-Pacific transport and North American forest fires on both O3 and CO at Whistler. Annual mean mixing ratios of O3 and CO were 41 ppbv (monthly means of 35–48 ppbv) and 145 ppbv (monthly means of 113–177 ppbv) respectively with both species exhibiting an annual cycle of late-winter to early-spring maxima and summer minima. The absence of a broad summer O3 peak differs from previously-reported high altitude sites in the western US. The highest monthly-averaged O3 and CO mixing ratios relative to the 5-yr monthly means were seen in fall 2002 and spring 2003 with increased O3 and CO of 10 % and 25 % respectively. These increases correspond to anomalously-high values reported at other Northern Hemisphere sites and are attributed to fires in the Russian Federation. Air mass back trajectory analysis is used to associate the mean enhancements of O3 and CO with trans-Pacific transported or North American air masses relative to the Pacific background. Mean values of the enhancements for March to June in trans-Pacific air masses were 6 ppbv and 16 ppbv for O3 and CO respectively. In summers 2002–2006, higher CO and O3 mixing ratios were almost always observed in North American air masses and this relative enhancement co-varied for each year with the western US and Canada total wildfire area. The greatest enhancements in O3 and CO were seen in 2004, a record year for forest fires in Alaska and the Yukon Territory with average O3 and CO mixing ratios 13 and 43 ppbv above background values.
Highlights
Factors affecting lower tropospheric ozone are important for the development of policies for local and regional pollution control as well as for evaluating the effectiveness of these controls
The percent of time during each available period that the site was in cloud at each hour of the day ranged from 8–20 % for entirely cloud covered to 15–40 % for greater than 10 min out of an hour
Cloud coverage increased from morning to afternoon with a decrease again at approximately 1600 (PST)
Summary
Factors affecting lower tropospheric ozone are important for the development of policies for local and regional pollution control as well as for evaluating the effectiveness of these controls. Similar trends have been identified in free tropospheric measurements through a comprehensive integration of data from multiple years and west coast studies (Cooper et al, 2010) Reasons for these trends are unclear and several possibilities have been suggested including regional continental or ship emissions, biomass burning and trans-Pacific transport (Cooper et al, 2010; Jaffe and Ray 2007; Dalsoren et al, 2010; Jaffe, 2010). Situated about 100 km from the west coast of Canada, the Whistler Peak site was established to provide a baseline of particles and trace gases in the lower free-troposphere, and to examine incidences of trans-Pacific transport of dust and pollution into western Canada. The summer enhancements observed in O3 and CO are related to the interannual variability of forest fires
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