Abstract. In this paper, measurements of air pollutants made at a ground site near Fort
McKay in the Athabasca oil sands region as part of a multi-platform campaign
in the summer of 2013 are presented. The observations included measurements
of selected volatile organic compounds (VOCs) by a gas chromatograph–ion
trap mass spectrometer (GC-ITMS). This instrument observed a large,
analytically unresolved hydrocarbon peak (with a retention index between 1100
and 1700) associated with intermediate-volatility organic compounds (IVOCs).
However, the activities or processes that contribute to the release of these
IVOCs in the oil sands region remain unclear. Principal component analysis (PCA) with varimax rotation was applied to
elucidate major source types impacting the sampling site in the summer of
2013. The analysis included 28 variables, including concentrations of total
odd nitrogen (NOy), carbon dioxide (CO2), methane
(CH4), ammonia (NH3), carbon monoxide (CO), sulfur
dioxide (SO2), total reduced-sulfur compounds (TRSs), speciated
monoterpenes (including α- and β-pinene and limonene),
particle volume calculated from measured size distributions of particles less
than 10 and 1 µm in diameter (PM10−1 and PM1),
particle-surface-bound polycyclic aromatic hydrocarbons (pPAHs), and aerosol
mass spectrometer composition measurements, including refractory black carbon
(rBC) and organic aerosol components. The PCA was complemented by bivariate
polar plots showing the joint wind speed and direction dependence of air
pollutant concentrations to illustrate the spatial distribution of sources in
the area. Using the 95 % cumulative percentage of variance criterion, 10
components were identified and categorized by source type. These included
emissions by wet tailing ponds, vegetation, open pit mining operations,
upgrader facilities, and surface dust. Three components correlated with
IVOCs, with the largest associated with surface mining and likely caused
by the unearthing and processing of raw bitumen.
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.
Abstract. Peroxy and peroxyacyl nitrates (PNs and PANs) are important trace gas constituents of the troposphere which are challenging to quantify by differential thermal dissociation with NO2 detection in polluted (i.e., high-NOx) environments. In this paper, a thermal dissociation peroxy radical chemical amplification cavity ring-down spectrometer (TD-PERCA-CRDS) for sensitive and selective quantification of total peroxynitrates (ΣPN = ΣRO2NO2) and of total peroxyacyl nitrates (ΣPAN = ΣRC(O)O2NO2) is described. The instrument features multiple detection channels to monitor the NO2 background and the ROx ( = HO2 + RO2 + ΣRO2) radicals generated by TD of ΣPN and/or ΣPAN. Chemical amplification is achieved through the addition of 0.6 ppm NO and 1.6 % C2H6 to the inlet. The instrument's performance was evaluated using peroxynitric acid (PNA) and peroxyacetic or peroxypropionic nitric anhydride (PAN or PPN) as representative examples of ΣPN and ΣPAN, respectively, whose abundances were verified by iodide chemical ionization mass spectrometry (CIMS). The amplification factor or chain length increases with temperature up to 69 ± 5 and decreases with analyte concentration and relative humidity (RH). At inlet temperatures above 120 and 250 °C, respectively, PNA and ΣPAN fully dissociated, though their TD profiles partially overlap. Furthermore, interference from ozone (O3) was observed at temperatures above 150 °C, rationalized by its partial dissociation to O atoms which react with C2H6 to form C2H5 and OH radicals. Quantification of PNA and ΣPAN in laboratory-generated mixtures containing O3 was achieved by simultaneously monitoring the TD-PERCA responses in multiple parallel CRDS channels set to different temperatures in the 60 to 130 °C range. The (1 s, 2σ) limit of detection (LOD) of TD-PERCA-CRDS is 6.8 pptv for PNA and 2.6 pptv for ΣPAN and significantly lower than TD-CRDS without chemical amplification. The feasibility of TD-PERCA-CRDS for ambient air measurements is discussed.
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