Low-volatility vapors and new particle formation over the Southern Ocean during the Antarctic Circumnavigation Expedition

Baccarini, Andrea; Dommen, Josef; Lehtipalo, Katrianne; Henning, S.; Modini, Rob L.; Gysel, M.; Baltensperger, Urs; Schmale, Julia

doi:10.1002/essoar.10506899.1

Cited by 6 publications

(9 citation statements)

References 112 publications

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“…To go further into the effect of aerosol acidity on the aerosol organic fraction, we select an organic molecule relevant for marine and Polar locations, MSA, which is produced from aqueous and gas phase oxidation of DMS, derived from dimethylsulfoniopropionate, a gas produced by phytoplankton 58 that participates in marine secondary aerosol formation 47,48,59,60 . MSA partitioning is mediated by gas-phase concentration, temperature, relative humidity and aerosol composition and properties 60 . To understand the effect of the warm air-mass intrusion together with changes in aerosol composition and acidity on MSA partitioning, we examine gas and particulate phase concentrations and variability.…”

Section: Changes In Aerosol Acidity and Msa Partitioningmentioning

confidence: 99%

“…The model was further used to calculate the partitioning of MSA between gas and particle phase 96 . The MSA properties are based on the values reported in Baccarini et al 60 . While there is a difference in the absolute value between measured and predicted partitioning, the relative difference between the background, first and second peaks remains visible.…”

Section: Determination Of Aerosol Aciditymentioning

confidence: 99%

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A central arctic extreme aerosol event triggered by a warm air-mass intrusion

et al. 2022

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Frequency and intensity of warm and moist air-mass intrusions into the Arctic have increased over the past decades and have been related to sea ice melt. During our year-long expedition in the remote central Arctic Ocean, a record-breaking increase in temperature, moisture and downwelling-longwave radiation was observed in mid-April 2020, during an air-mass intrusion carrying air pollutants from northern Eurasia. The two-day intrusion, caused drastic changes in the aerosol size distribution, chemical composition and particle hygroscopicity. Here we show how the intrusion transformed the Arctic from a remote low-particle environment to an area comparable to a central-European urban setting. Additionally, the intrusion resulted in an explosive increase in cloud condensation nuclei, which can have direct effects on Arctic clouds’ radiation, their precipitation patterns, and their lifetime. Thus, unless prompt actions to significantly reduce emissions in the source regions are taken, such intrusion events are expected to continue to affect the Arctic climate.

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Section: Changes In Aerosol Acidity and Msa Partitioningmentioning

confidence: 99%

Section: Determination Of Aerosol Aciditymentioning

confidence: 99%

A central arctic extreme aerosol event triggered by a warm air-mass intrusion

et al. 2022

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“…A2). This increase was caused by the strongest new particle formation event measured during the entire expedition (Baccarini et al, 2021). In fact, this event constitutes the most pronounced difference in the time series of LV1 (climatic zones and large-scale horizontal gradients) and LV14 (hotspot-driven climatic zones).…”

Section: Hotspots Of Latent Variable Activationmentioning

confidence: 95%

Exploring the coupled ocean and atmosphere system with a data science approach applied to observations from the Antarctic Circumnavigation Expedition

Schmale

2022

Preprint

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The Southern Ocean is a critical component of Earth&#8217;s climate system, but its remoteness makes it challenging to develop a holistic understanding of its processes from the small scale to the large scale. The Antarctic Circumnavigation Expedition (ACE, austral summer 2016/2017) surveyed a large number of variables describing the state of the ocean and the atmosphere, the freshwater cycle, atmospheric chemistry, and ocean biogeochemistry and microbiology. This circumpolar cruise included visits to 12 remote islands, the marginal ice zone, and the Antarctic coast.Here, we use 111 of the observed variables to study the latitudinal gradients, seasonality, shorter-term variations, geographic setting of environmental processes, and interactions between them over the duration of 90 days. To reduce the dimensionality and complexity of the dataset and make the relations between variables interpretable we applied an unsupervised machine learning method, the sparse principal component analysis (sPCA), which describes environmental processes through 14 latent variables.Our results provide a proof of concept that sPCA with uncertainty analysis is able to identify temporal patterns from diurnal to seasonal cycles, as well as geographical gradients and &#8220;hotspots&#8221; of interaction between environmental compartments. Our analysis provides novel insights into the Southern Ocean water cycle, atmospheric trace gases, and microbial communities. More specifically, we<ul><li>identify the important role of the oceanic circulations, frontal zones, and islands in shaping the nutrient availability that controls biological community composition and productivity;</li> <li>find that sea ice controls sea water salinity, dampens the wave field, and is associated with increased phytoplankton growth and net community productivity possibly due to iron fertilisation and reduced light limitation;</li> <li>elucidate the clear regional patterns of aerosol characteristics, stressing the role of the sea state, atmospheric chemical processing, and source processes near hotspots for the availability of cloud condensation nuclei and hence cloud formation.</li> </ul>A set of key variables and their combinations, such as the difference between the air and sea surface temperature, atmospheric pressure, sea surface height, geostrophic currents, upper-ocean layer light intensity, surface wind speed and relative humidity played an important role in our analysis, highlighting the necessity for Earth system models to represent them adequately.In conclusion, our study highlights the use of sPCA to identify key ocean&#8211;atmosphere interactions across physical, chemical, and biological processes and their associated spatio-temporal scales. It thereby fills an important gap between simple correlation analyses and complex Earth system models.The paper and links to data are available here: https://esd.copernicus.org/articles/12/1295/2021/

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“…This hypothesis is supported by the higher importance of OHinitiated DMS oxidation at lower latitudes in the study by Fung et al (2022), and the DMS conversion yields of MSA and HPMTF in the different model runs by Wollesen de Jonge et al ( 2021), where the HPMTF/MSA ratio was considerably lower in the AtmMain case compared to cases with higher temperature and lower RH. This could be both due to differing sources and sinks, such as dry/wet deposition of MSA (Bergin et al, 1995) and HPMTF (Khan et al, 2021), heterogeneous oxidation of MSA (g) (Mungall et al, 2018) and evaporation of MSA from the particle-to the gas phase (Baccarini et al, 2021).…”

Section: Gas-phase Dms Oxidation Productsmentioning

confidence: 99%

Arctic observations of Hydroperoxymethyl Thioformate (HPMTF) – seasonal behavior and relationship to other oxidation products from Dimethyl Sulfide at the Zeppelin Observatory, Svalbard

Siegel

Gramlich

Haslett

et al. 2023

Preprint

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Abstract. Dimethyl sulfide (DMS), a gas produced by phytoplankton, is the largest source of atmospheric sulfur over marine areas. DMS undergoes oxidation in the atmosphere to form a range of oxidation products, out of which methanesulfonic acid (MSA) and sulfuric acid (SA) are well-known for participating in the formation and growth of atmospheric aerosol particles. Recently, a new oxidation product of DMS, hydroperoxymethyl thioformate (HPMTF) was discovered and later also measured in the atmosphere. Little is still known about the fate of this compound and its potential to partition to the particle phase. In this study, we present a full year (2020) of concurrent gas- and particle-phase observations of HPMTF, MSA, SA and other DMS oxidation products at the Zeppelin Observatory (Ny-Ålesund, Svalbard) located in the Arctic. This is the first time HPMTF has been measured in Svalbard and attempted to be observed in atmospheric particles. The results show that gas-phase HPMTF concentrations largely follow the same pattern as MSA during the sunlit months (April–September), indicating production of HPMTF around Svalbard. However, HPMTF was not observed in significant amounts in the particle phase, despite high gas-phase levels. Particulate MSA and SA were observed during the sunlit months, although the highest median levels of particulate SA were measured in February, coinciding with the highest gaseous SA levels with assumed anthropogenic origin. We further show that gas- and particle-phase MSA and SA are coupled in May–July, whereas HPMTF lies outside of this correlation due to the low particulate concentrations. These results provide more information about the relationship between HPMTF and other DMS oxidation products in a part of the world where these have not been explored yet, and about HPMTF’s ability to contribute to particle growth and cloud formation.

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Low-volatility vapors and new particle formation over the Southern Ocean during the Antarctic Circumnavigation Expedition

Cited by 6 publications

References 112 publications

A central arctic extreme aerosol event triggered by a warm air-mass intrusion

A central arctic extreme aerosol event triggered by a warm air-mass intrusion

Exploring the coupled ocean and atmosphere system with a data science approach applied to observations from the Antarctic Circumnavigation Expedition

Arctic observations of Hydroperoxymethyl Thioformate (HPMTF) – seasonal behavior and relationship to other oxidation products from Dimethyl Sulfide at the Zeppelin Observatory, Svalbard

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