Abstract. The nocturnal nitrogen oxides, which include the nitrate radical (NO3),
dinitrogen pentoxide (N2O5), and its uptake product on chloride
containing aerosol, nitryl chloride (ClNO2), can have profound impacts
on the lifetime of NOx (= NO + NO2), radical budgets, and
next-day photochemical ozone (O3) production, yet their abundances and
chemistry are only sparsely constrained by ambient air measurements. Here, we present a measurement data set collected at a routine monitoring
site near the Abbotsford International Airport (YXX) located approximately
30 km from the Pacific Ocean in the Lower Fraser Valley (LFV) on the west
coast of British Columbia. Measurements were made from 20 July to 4 August
2012 and included mixing ratios of ClNO2, N2O5, NO,
NO2, total odd nitrogen (NOy), O3, photolysis frequencies,
and size distribution and composition of non-refractory submicron aerosol
(PM1). At night, O3 was rapidly and often completely removed by dry deposition
and by titration with NO of anthropogenic origin and unsaturated biogenic
hydrocarbons in a shallow nocturnal inversion surface layer. The low
nocturnal O3 mixing ratios and presence of strong chemical sinks for
NO3 limited the extent of nocturnal nitrogen oxide chemistry at ground
level. Consequently, mixing ratios of N2O5 and ClNO2 were low
(< 30 and < 100 parts-per-trillion by volume (pptv) and
median nocturnal peak values of 7.8 and 7.9 pptv, respectively). Mixing
ratios of ClNO2 frequently peaked 1–2 h after sunrise
rationalized by more efficient formation of ClNO2 in the nocturnal
residual layer aloft than at the surface and the breakup of the nocturnal
boundary layer structure in the morning. When quantifiable, production of
ClNO2 from N2O5 was efficient and likely occurred
predominantly on unquantified supermicron-sized or refractory sea-salt-derived aerosol. After sunrise, production of Cl radicals from photolysis of
ClNO2 was negligible compared to production of OH from the reaction of
O(1D) + H2O except for a short period after sunrise.
Routine monitoring stations on the west coast of North America serve to monitor baseline levels of criteria pollutants such as ozone (O3) arriving from the Pacific Ocean. In Canada, the Amphitrite Point Observatory (APO) on Vancouver Island has been added to this network to provide regional baseline measurements. In 2014, McKendry and co-workers reported frequent nocturnal O3 depletion events (ODEs) at APO that generally correlated with alongshore winds, elevated concentrations of carbon dioxide (CO2) and stable boundary layer conditions, but whose cause (or causes) has (have) remained unclear.This manuscript presents results from the Ozone-depleting Reactions in a Coastal Atmosphere (ORCA) campaign, which took place in July, 2015 to further investigate ODEs at APO. In addition to the long-term measurements at the site (e.g., of CO2 and O3 mixing ratios), abundances of biogenic volatile organic compounds (BVOC) and aerosol size distributions were quantified. ODEs were observed on the majority of measurement nights and were characterized by a simultaneous increase of CO2 and BVOC abundances, in particular of limonene, a terpene 2.5 more reactive with respect to oxidation of O3 than other monoterpenes.Back trajectory calculations showed that ODEs occurred mainly in air masses that originated from the WNW where the air would have travelled parallel to the coastline and above kelp forests. Head space analyses of sea weed samples showed that bull kelp is a source of gas-phase limonene, consistent with its high relative abundance in air masses from the WNW sector. However, the enhanced terpene and CO2 content showed that the air likely also came in contact with terrestrial vegetation via mesoscale transport phenomena (such as slope flows and land-sea breeze circulations) that were generally poorly captured by the back trajectories. This absence of aerosol growth during ODEs indicates that dry deposition is likely the primary O3 loss mechanism.
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