Regions of open water and melting sea ice drive new particle formation in North East Greenland

Osto, M. Dall; Geels, Camilla; Beddows, D. C. S.; Boertmann, David; Lange, Robert; Nøjgaard, Jakob Klenø; Harrison, Roy M.; Simó, Rafel; Skov, Henrik; Maßling, Andreas

doi:10.1038/s41598-018-24426-8

Cited by 53 publications

(73 citation statements)

References 69 publications

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“…In addition, only Browse et al () included SOA formation, but their model considered only monoterpenes from terrestrial sources as possible aerosol precursors. Importantly, modeling studies have not captured the increased particle formation with decreasing sea ice extent observed by Dall'Osto et al (, ; Figure ).…”

Section: Regional Arctic Processesmentioning

confidence: 93%

“…Few studies have attempted to quantify the impact of Arctic warming and sea ice loss on natural aerosol. Notably, the occurrence of particle nucleation events at both Zeppelin and Nord has been anti‐correlated with sea ice extent in the last decade (Figure ); decreased sea ice extent is related to increased frequency of particle formation and growth during summer (Dall'Osto et al, , ). This work has further shown that particle formation occurred when air masses had traveled over areas of open water and broken ice, highlighting the importance of both open water and marginal ice zones as sources of aerosol precursors.…”

Section: Regional Arctic Processesmentioning

confidence: 99%

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Processes Controlling the Composition and Abundance of Arctic Aerosol

Willis

Leaitch

Abbatt

2018

Reviews of Geophysics

143

154

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The Arctic region is a harbinger of global change and is warming at a rate higher than the global average. While Arctic warming is driven by increases in anthropogenic greenhouse gases' in combination with local feedback mechanisms, short‐lived climate forcing agents, such as tropospheric aerosol, are also important drivers of Arctic climate. Arctic aerosol‐climate impacts vary seasonally as a result of the interplay between aerosol and different cloud types, available solar radiation, sea ice, surface albedo, Arctic and lower latitude removal processes, and atmospheric transport patterns. Photochemistry and efficient wet aerosol removal have low impact in winter but become important in spring to summer, dramatically altering aerosol chemical composition, and driving the size distribution from a pronounced accumulation mode toward a dominance of smaller particles. Retreating sea ice, increasing solar insolation and warmer temperatures in summer result in enhanced emissions from Arctic marine and terrestrial ecosystems, and anthropogenic sources, with impacts on the composition of gas and particle phases. Fractional cloud cover reaches a maximum in Arctic summer, in parallel with decreasing sea ice extent and surface albedo. This seasonal variation corresponds to significant changes in the net cloud radiative effect; changes that are affected by aerosol. This review summarizes our current knowledge of processes that control Arctic aerosol properties. We highlight both natural and anthropogenic processes that will be impacted by current and future sea ice loss. Efforts are needed to better constrain aerosol removal rates, characterize aerosol precursors, and constrain the seasonality and magnitude of aerosol‐cloud‐climate impacts.

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Section: Regional Arctic Processesmentioning

confidence: 93%

Section: Regional Arctic Processesmentioning

confidence: 99%

Processes Controlling the Composition and Abundance of Arctic Aerosol

Willis

Leaitch

Abbatt

2018

Reviews of Geophysics

143

154

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“…S6b, d). Following terminology developed in previous work (Dall'Osto et al, 2017a, 2018b the remaining aerosol clusters can be classified as follows:…”

Section: K-mean Smps Cluster Analysismentioning

confidence: 99%

“…First, Dall'Osto et al (2017a) suggested that the microbiota of sea ice and the sea-ice-influenced ocean were a significant source of atmospheric nucleating particles concentrations (N 1-3 nm ). Second, within two different Arctic locations across large temporal scales (2000)(2001)(2002)(2003)(2004)(2005)(2006)(2007)(2008)(2009)(2010)(2011)(2012)(2013)(2014)(2015)(2016) new particle formation was associated with air mass back trajectories passing over open water and melting-sea-ice regions, also pointing to marine biological activities within the open leads in the pack ice and/or along the melting marginal sea ice zone (MIZ) being responsible for such events (Dall'Osto et al, 2017b, 2018b. Our data from Halley and the brief intercomparison with two other stations suggest that the size distributions of Antarctic sub-micrometre aerosols may have been oversimplified in the past (Ito, 1993) and that complex interactions between multiple ecosystems, coupled with different atmospheric circulation, result in very different aerosol size distributions populating the Southern Hemisphere.…”

Section: Implication For Climate and Conclusionmentioning

confidence: 99%

On the annual variability of Antarctic aerosol size distributions at Halley Research Station

et al. 2020

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The Southern Ocean and Antarctic region currently best represent one of the few places left on our planet with conditions similar to the preindustrial age. Currently, climate models have a low ability to simulate conditions forming the aerosol baseline; a major uncertainty comes from the lack of understanding of aerosol size distributions and their dynamics. Contrasting studies stress that primary sea salt aerosol can contribute significantly to the aerosol population, challenging the concept of climate biogenic regulation by new particle formation (NPF) from dimethyl sulfide marine emissions.We present a statistical cluster analysis of the physical characteristics of particle size distributions (PSDs) collected at Halley (Antarctica) for the year 2015 (89 % data coverage; 6-209 nm size range; daily size resolution). By applying the Hartigan-Wong k-mean method we find eight clusters describing the entire aerosol population. Three clusters show pristine average low particle number concentrations (< 121-179 cm −3 ) with three main modes (30, 75-95 and 135-160 nm) and represent 57 % of the annual PSD (up to 89 %-100 % during winter and 34 %-65 % during summer based on monthly averages). Nucleation and Aitken mode PSD clusters dominate summer months (September-January, 59 %-90 %), whereas a clear bimodal distribution (43 and 134 nm, respectively; Hoppel minimum at mode 75 nm) is seen only during the December-April period (6 %-21 %). Major findings of the current work include: (1) NPF and growth events originate from both the sea ice marginal zone and the Antarctic plateau, strongly suggesting multiple vertical origins, including the marine boundary layer and free troposphere; (2) very low particle number concentrations are detected for a substantial part of the year (57 %), including summer (34 %-65 %), suggesting that the strong annual aerosol concentration cycle is driven by a short temporal interval of strong NPF events; (3) a unique pristine aerosol cluster is seen with a bimodal size distribution (75 and 160 nm, respectively), strongly associated with high wind speed and possibly associated with blowing snow and sea spray sea salt, dominating the winter aerosol population (34 %-54 %). A brief comparison with two other stations (Dome C -Concordia -and King Sejong Station) during the year 2015 (240 d overlap) shows that the dynamics of aerosol number concentrations and distributions are more complex than the simple sulfate-sea-spray binary combination, and it is likely that an array of additional chemical components and processes drive the aerosol population. A conceptual illustra-Published by Copernicus Publications on behalf of the European Geosciences Union. 4462T. Lachlan-Cope et al.: Annual variability of Antarctic aerosol size distributions tion is proposed indicating the various atmospheric processes related to the Antarctic aerosols, with particular emphasis on the origin of new particle formation and growth.

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“…Bubble-bursting and jet drops at the ocean surface result in the production of sea spray particles composed of inorganic sea salt and organic matter (e.g., de Leeuw et al, 2011;Quinn and Bates, 2014). Among various atmospheric aerosol components, sea salt is estimated to have the largest mass emission flux and the second-largest atmospheric mass loading globally (Textor et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

Observationally constrained analysis of sea salt aerosol in the marine atmosphere

et al. 2019

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Abstract. Atmospheric sea salt plays important roles in marine cloud formation and atmospheric chemistry. We performed an integrated analysis of NASA GEOS model simulations run with the GOCART aerosol module, in situ measurements from the PALMS and SAGA instruments obtained during the NASA ATom campaign, and aerosol optical depth (AOD) measurements from the AERONET Marine Aerosol Network (MAN) and from MODIS satellite observations to better constrain sea salt in the marine atmosphere. ATom measurements and GEOS model simulations both show that sea salt concentrations over the Pacific and Atlantic oceans have a strong vertical gradient, varying up to 4 orders of magnitude from the marine boundary layer to free troposphere. The modeled residence times suggest that the lifetime of sea salt particles with a dry diameter of less than 3 µm is largely controlled by wet removal, followed by turbulent process. During both boreal summer and winter, the GEOS-simulated sea salt mass mixing ratios agree with SAGA measurements in the marine boundary layer (MBL) and with PALMS measurements above the MBL. However, comparison of AOD from GEOS with AERONET/MAN and MODIS aerosol retrievals indicated that the model underestimated AOD over the oceans where sea salt dominates. The apparent discrepancy of slightly overpredicted concentration and large underpredicted AOD could not be explained by biases in the model RH affecting the particle hygroscopic growth, as modeled RH was found to be comparable to or larger than the in situ measurements. This conundrum could at least partially be explained by the difference in sea salt size distribution; the GEOS simulation has much less sea salt percentage-wise in the smaller particle size range and thus less efficient light extinction than what was observed by PALMS.

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Regions of open water and melting sea ice drive new particle formation in North East Greenland

Cited by 53 publications

References 69 publications

Processes Controlling the Composition and Abundance of Arctic Aerosol

Processes Controlling the Composition and Abundance of Arctic Aerosol

On the annual variability of Antarctic aerosol size distributions at Halley Research Station

Observationally constrained analysis of sea salt aerosol in the marine atmosphere

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