Marine productivity and synoptic meteorology drive summer-time variability in Southern Ocean aerosols

Cloud–radiation interactions over the Southern Ocean are not well constrained in climate models, in part due to uncertainties in the sources, concentrations, and cloud-forming potential of aerosol in this region. To date, most studies in this region have reported measurements from fixed terrestrial...

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Bibliographic Details
Published in:Atmospheric Chemistry and Physics
Main Authors: J. Alroe, L. T. Cravigan, B. Miljevic, G. R. Johnson, P. Selleck, R. S. Humphries, M. D. Keywood, S. D. Chambers, A. G. Williams, Z. D. Ristovski
Format: Article in Journal/Newspaper
Language:English
Published: Copernicus Publications 2020
Subjects:
Physics
QC1-999
Chemistry
QD1-999
Antarctic
Southern Ocean
Austral
Aitken
Antarc*
Online Access:https://doi.org/10.5194/acp-20-8047-2020
https://doaj.org/article/48d73464f47f49909893e3c4b18528d7
Description
Summary:Cloud–radiation interactions over the Southern Ocean are not well constrained in climate models, in part due to uncertainties in the sources, concentrations, and cloud-forming potential of aerosol in this region. To date, most studies in this region have reported measurements from fixed terrestrial stations or a limited set of instrumentation and often present findings as broad seasonal or latitudinal trends. Here, we present an extensive set of aerosol and meteorological observations obtained during an austral summer cruise across the full width of the Southern Ocean south of Australia. Three episodes of continental-influenced air masses were identified, including an apparent transition between the Ferrel atmospheric cell and the polar cell at approximately 64 ∘ S, and accompanied by the highest median cloud condensation nuclei (CCN) concentrations, at 252 cm −3 . During the other two episodes, synoptic-scale weather patterns diverted air masses across distances greater than 1000 km from the Australian and Antarctic coastlines, respectively, indicating that a large proportion of the Southern Ocean may be periodically influenced by continental air masses. In all three cases, a highly cloud-active accumulation mode dominated the size distribution, with up to 93 % of the total number concentration activating as CCN. Frequent cyclonic weather conditions were observed at high latitudes and the associated strong wind speeds led to predictions of high concentrations of sea spray aerosol. However, these modelled concentrations were not achieved due to increased aerosol scavenging rates from precipitation and convective transport into the free troposphere, which decoupled the air mass from the sea spray flux at the ocean surface. CCN concentrations were more strongly impacted by high concentrations of large-diameter Aitken mode aerosol in air masses which passed over regions of elevated marine biological productivity, potentially contributing up to 56 % of the cloud condensation nuclei concentration. Weather systems ...

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