Influence of transport and ocean ice extent on biogenic aerosol sulfur in the Arctic atmosphere

Sharma, Sangeeta; Chan, Elton; Ishizawa, Misa; Toom-Sauntry, D.; Gong, S. L.; Li, Shao-Meng; Tarasick, D. W.; Leaitch, W. R.; Norman, Ann‐Lise; Quinn, Patricia K.; Bates, T.; Levasseur, Maurice; Barrie, L. A.; Maenhaut, Willy

doi:10.1029/2011jd017074

Cited by 109 publications

(190 citation statements)

References 67 publications

(77 reference statements)

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“…There have been no significant trends in either sulfate or BC at the observatory in Barrow, Alaska (Hirdman et al, 2010). Although measurements of methane sulfonic acid (MSA) from 1980 to 2009 show no net change in MSA at Alert (Sharma et al, 2012), MSA did increase from 2000 to 2009 associated with the northward migration of the marginal ice zone Sharma et al, 2012;Laing et al, 2013). Of the four northernmost observatories, the highest MSA concentrations are measured at Mount Zeppelin, likely due to its proximity to the waters between Greenland and northern Europe, that are a significant source of DMS from May to August (e.g., Lana et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Organic functional groups in the submicron aerosol at 82.5° N, 62.5° W from 2012 to 2014

et al. 2018

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Abstract. The first multi-year contributions from organic functional groups to the Arctic submicron aerosol are documented using 126 weekly-integrated samples collected from April 2012 to October 2014 at the Alert Observatory (82.45 • N, 62.51 • W). Results from the particle transport model FLEXPART, linear regressions among the organic and inorganic components and positive matrix factorization (PMF) enable associations of organic aerosol components with source types and regions. Lower organic mass (OM) concentrations but higher ratios of OM to non-sea-salt sulfate mass concentrations (nss-SO = 4 ) accompany smaller particles during the summer (JJA). Conversely, higher OM but lower OM / nss-SO = 4 accompany larger particles during winter-spring. OM ranges from 7 to 460 ng m −3 , and the study average is 129 ng m −3 . The monthly maximum in OM occurs during May, 1 month after the peak in nss-SO = 4 and 2 months after that of elemental carbon (EC). Winter (DJF), spring (MAM), summer and fall (SON) values of OM / nss-SO = 4 are 26, 28, 107 and 39 %, respectively, and overall about 40 % of the weekly variability in the OM is associated with nss-SO = 4 . Respective study-averaged concentrations of alkane, alcohol, acid, amine and carbonyl groups are 57, 24, 23, 15 and 11 ng m −3 , representing 42, 22, 18, 14 and 5 % of the OM, respectively. Carbonyl groups, detected mostly during spring, may have a connection with snow chemistry. The seasonally highest O / C occurs during winter (0.85) and the lowest O / C is during spring (0.51); increases in O / C are largely due to increases in alcohol groups. During winter, more than 50 % of the alcohol groups are associated with primary marine emissions, consistent with Shaw et al. (2010) and Frossard et al. (2011). A secondary marine connection, rather than a primary source, is suggested for the highest and most persistent O / C observed during the coolest and cleanest summer (2013), when alcohol and acid groups made up 63 % of the OM. A secondary marine source may be a general feature of the summer OM, but higher contributions from alkane groups to OM during the warmer summers of 2012 (53 %) and 2014 (50 %) were likely due to increased contributions from combustion sources. Evidence for significant contributions from biomass burning (BB) was present in 4 % of the weeks. During the dark months (NDJF), 29, 28 and 14 % of the nss-SO = 4 , EC and OM were associated with transport times over the gas flaring region of northern Russia and other parts of Eurasia. During spring, those percentages dropped to 11 % for each of nss-SO = 4 and EC values, respectively, and there is no association of OM.

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Section: Introductionmentioning

confidence: 99%

Organic functional groups in the submicron aerosol at 82.5° N, 62.5° W from 2012 to 2014

et al. 2018

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“…This is of course dependent on a nucleating gas and its precursors, which could be either locally emitted, e.g. DMS from the ocean (Sharma et al, 2012), or, perhaps less likely, transported into the Arctic during certain transport conditions. Single particle analysis (Behrenfeldt et al, 2008) further indicates that samples taken before the rapid transition mainly consisted of spherical "organic-like" particles originating from Eurasia, while particles sampled after the transition are associated with an enhanced abundance of particles associated with both marine sources within the Arctic (e.g.…”

Section: Strong Seasonal Variation Of the Aerosol Size Distribution Pmentioning

confidence: 99%

Arctic aerosol life cycle: linking aerosol size distributions observed between 2000 and 2010 with air mass transport and precipitation at Zeppelin station, Ny-Ålesund, Svalbard

2013

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In this study we present a qualitative and quantitative assessment of more than 10 yr of aerosol number size distribution data observed in the Arctic environment (Mt. Zeppelin (78°56' N, 11°53' E, 474 m a.s.l.), Ny Ålesund, Svalbard). We provide statistics on both seasonal and diurnal characteristics of the aerosol observations and conclude that the Arctic aerosol number size distribution and related parameters such as integral mass and surface area exhibit a very pronounced seasonal variation. This seasonal variation seems to be controlled by both dominating source as well as meteorological conditions. Three distinctly different periods can be identified during the Arctic year: the haze period characterized by a dominating accumulation mode aerosol (March–May), followed by the sunlit summer period with low abundance of accumulation mode particles but high concentration of small particles which are likely to be recently and locally formed (June–August). The rest of the year is characterized by a comparably low concentration of accumulation mode particles and negligible abundance of ultrafine particles (September–February). A minimum in aerosol mass and number concentration is usually observed during September/October.

We further show that the transition between the different regimes is fast, suggesting rapid change in the conditions defining their appearance. A source climatology based on trajectory analysis is provided, and it is shown that there is a strong seasonality of dominating source areas, with Eurasia dominating during the Autumn–Winter period and dominance of North Atlantic air during the summer months. We also show that new-particle formation events are rather common phenomena in the Arctic during summer, and this is the result of photochemical production of nucleating/condensing species in combination with low condensation sink. It is also suggested that wet removal may play a key role in defining the Arctic aerosol year, via the removal of accumulation mode size particles, which in turn have a pivotal role in facilitating the conditions favorable for new-particle formation events. In summary the aerosol Arctic year seems to be at least qualitatively predictable based on the knowledge of seasonality of transport paths and associated source areas, meteorological conditions and removal processes

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“…In the Arctic, interactions between aerosol, clouds, and climate are complicated by a combination of high surface albedo; the dependence of cloud emissivity on droplet size and aerosol properties [e.g., Curry, 1995;Lubin and Vogelmann, 2006;Kay and Gettelman, 2009]; and the seasonal cycle in aerosol concentration, size, and composition [e.g., Shaw, 1995;Quinn et al, 2007;Sharma et al, 2012;Breider et al, 2014;Croft et al, 2016a]. Aerosol can exert a strong influence on Arctic climate, and changes in anthropogenic aerosol concentrations likely contributed to the magnitude of Arctic warming and impacted sea ice concentrations in recent decades [Najafi et al, 2015;Acosta Navarro et al, 2016;Gagné et al, 2017].…”

Section: Introductionmentioning

confidence: 99%

Evidence for marine biogenic influence on summertime Arctic aerosol

Willis

Köllner

Burkart

et al. 2017

Geophysical Research Letters

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We present vertically resolved observations of aerosol composition during pristine summertime Arctic background conditions. The methansulfonic acid (MSA)‐to‐sulfate ratio peaked near the surface (mean 0.10), indicating a contribution from ocean‐derived biogenic sulfur. Similarly, the organic aerosol (OA)‐to‐sulfate ratio increased toward the surface (mean 2.0). Both MSA‐to‐sulfate and OA‐to‐sulfate ratios were significantly correlated with FLEXPART‐WRF‐predicted air mass residence time over open water, indicating marine‐influenced OA. External mixing of sea salt aerosol from a larger number fraction of organic, sulfate, and amine‐containing particles, together with low wind speeds (median 4.7 m s−1), suggests a role for secondary organic aerosol formation. Cloud condensation nuclei concentrations were nearly constant (∼120 cm−3) when the OA fraction was <60% and increased to 350 cm−3 when the organic fraction was larger and residence times over open water were longer. Our observations illustrate the importance of marine‐influenced OA under Arctic background conditions, which are likely to change as the Arctic transitions to larger areas of open water.

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Influence of transport and ocean ice extent on biogenic aerosol sulfur in the Arctic atmosphere

Cited by 109 publications

References 67 publications

Organic functional groups in the submicron aerosol at 82.5° N, 62.5° W from 2012 to 2014

Organic functional groups in the submicron aerosol at 82.5° N, 62.5° W from 2012 to 2014

Arctic aerosol life cycle: linking aerosol size distributions observed between 2000 and 2010 with air mass transport and precipitation at Zeppelin station, Ny-Ålesund, Svalbard

Evidence for marine biogenic influence on summertime Arctic aerosol

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Influence of transport and ocean ice extent on biogenic aerosol sulfur in the Arctic atmosphere

Cited by 109 publications

References 67 publications

Organic functional groups in the submicron aerosol at 82.5° N, 62.5° W from 2012 to 2014

Organic functional groups in the submicron aerosol at 82.5° N, 62.5° W from 2012 to 2014

Arctic aerosol life cycle: linking aerosol size distributions observed between 2000 and 2010 with air mass transport and precipitation at Zeppelin station, Ny-Ålesund, Svalbard

Evidence for marine biogenic influence on summertime Arctic aerosol

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Resources

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Organic functional groups in the submicron aerosol at 82.5° N, 62.5° W from 2012 to 2014

Organic functional groups in the submicron aerosol at 82.5° N, 62.5° W from 2012 to 2014