Abstract

Abstract. Measurements of atmospheric nitrogen oxides NOx (NOx = NO + NO2), peroxyacetyl nitrate (PAN), NOy, and non-methane hydrocarbons (NMHC) were taken at the Greenland Environmental Observatory at Summit (GEOSummit) station, Greenland (72.34° N, 38.29° W; 3212 m a.s.l.), from July 2008 to July 2010. The data set represents the first year-round concurrent record of these compounds sampled at a high latitude Arctic site. Here, the study focused on the seasonal variability of these important ozone (O3) precursors in the Arctic troposphere and the impact from transported anthropogenic and biomass burning emissions. Our analysis shows that PAN is the dominant NOy species in all seasons at Summit, varying from 42 to 76 %; however, we find that odd NOy species (odd NOy = NOy − PAN − NOx) contribute a large amount to the total NOy speciation. We hypothesize that the source of this odd NOy is most likely alkyl nitrates and nitric acid (HNO3) from transported pollution, and photochemically produced species such as nitrous acid (HONO). FLEXPART retroplume analyses and black carbon (BC) tracers for anthropogenic and biomass burning (BB) emissions were used to identify periods when the site was impacted by polluted air masses. Europe contributed the largest source of anthropogenic emissions during the winter months (November–March) with 56 % of the total anthropogenic BC tracer originating from Europe in 2008–2009 and 69 % in 2009–2010. The polluted plumes resulted in mean enhancements above background levels up to 334, 295, 88, and 1119 pmol mol−1 for NOy, PAN, NOx, and ethane, respectively, over the two winters. Enhancements in O3 precursors during the second winter were typically higher, which may be attributed to the increase in European polluted air masses transported to Summit in 2009–2010 compared to 2008–2009. O3 levels were highly variable within the sampled anthropogenic plumes with mean ΔO3 levels ranging from −6.7 to 7.6 nmol mol−1 during the winter periods. North America was the primary source of biomass burning emissions during the summer; however, only 13 BB events were observed as the number of air masses transported to Summit, with significant BB emissions, was low in general during the measurement period. The BB plumes were typically very aged, with median transport times to the site from the source region of 14 days. The analyses of O3 and precursor levels during the BB events indicate that some of the plumes sampled impacted the atmospheric chemistry at Summit, with enhancements observed in all measured species.

Highlights

  • The seasonality of ozone (O3) and its precursors for photochemical production, such as nitrogen oxides, i.e. NOx (NOx = NO + NO2), peroxyacetyl nitrate (PAN), and nonmethane hydrocarbons (NMHC), in the remote Arctic troposphere is governed by a combination of transport pathways, photochemistry, and stratospheric influx (Klonecki et al, 2003; Stohl et al, 2006; Law and Stohl, 2007; Liang et al, 2011)

  • Anthropogenic and biomass burning emissions transported to the site from North America and Europe are a major source of these enhancements

  • Observations from the Arctic Research of the Composition of the Troposphere from Aircraft and Satellites (ARCTAS) mission in 2008 showed that mixed stratospheric–tropospheric air masses, above 5 km, have elevated levels of O3 precursors such as NOx and HNO3, which can subsequently be converted to PAN (Liang et al, 2011)

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Summary

Introduction

FLEXPART retroplume analyses indicate that low O3 events over winter typically coincide when sampling air masses originating from either Europe or North America, which have resided in the lower troposphere and/or are quickly transported over the Greenland ice sheet to the measurement site (examples of FLEXPART retroplumes are shown in Fig. S8a–e in the Supplement). Periods identified during winter as pollution events with positive O3 enhancement values often occurred when the air masses resided in the mid-troposphere during transport to the site (Fig. S9a–e), allowing for greater mixing with air from high tropospheric or stratospheric origin. Results show that enhancements in O3 and O3 precursors during events were typically higher durwww.atmos-chem-phys.net/15/6827/2015/

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