The transformation of Arctic clouds with warming

Abstract The progressive loss of Arctic sea ice leads to increased surface emissions of Dimethyl Sulphide (DMS), which is the dominant local source of sulphate aerosols. We test the hypothesis that cloud condensation nuclei, derived from DMS, will increase cloud-top albedo in an earth-system global...

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Bibliographic Details
Main Authors: J. K. Ridley, M. A. Ringer, R. M. Sheward
Format: Article in Journal/Newspaper
Language:unknown
Subjects:
Arctic
Arctic Ocean
albedo
Sea ice
Online Access:http://link.springer.com/10.1007/s10584-016-1772-4
id ftrepec:oai:RePEc:spr:climat:v:139:y:2016:i:2:d:10.1007_s10584-016-1772-4
record_format openpolar
spelling ftrepec:oai:RePEc:spr:climat:v:139:y:2016:i:2:d:10.1007_s10584-016-1772-4 2023-05-15T13:10:50+02:00 The transformation of Arctic clouds with warming J. K. Ridley M. A. Ringer R. M. Sheward http://link.springer.com/10.1007/s10584-016-1772-4 unknown http://link.springer.com/10.1007/s10584-016-1772-4 article ftrepec 2020-12-04T13:42:16Z Abstract The progressive loss of Arctic sea ice leads to increased surface emissions of Dimethyl Sulphide (DMS), which is the dominant local source of sulphate aerosols. We test the hypothesis that cloud condensation nuclei, derived from DMS, will increase cloud-top albedo in an earth-system global climate model. The earth-system model includes fully interactive ocean biology, DMS, atmospheric chemistry, aerosols and cloud microphysics. In an idealised warming scenario, the Arctic Ocean becomes ice-free in summer when atmospheric CO2 is increased by 1 % per year to four times the pre-industrial concentrations. The summer boundary layer near-surface inversion strengthens, increasing stratification with warming, whilst the autumn inversion weakens. We find that the dominant change in cloud albedo arises from the conversion of summer clouds from ice to liquid, reducing the solar flux at the surface by 27 W m−2. Only 1–2 W m−2 of the reduced solar flux is attributed to cloud condensation nuclei associated with sulphate aerosols derived from the 2–5 fold increase in DMS emissions that results from an ice-free ocean. We conclude that aerosol-cloud feedbacks originating from DMS production in the Arctic region are largely mitigated through increased wet deposition of sulphate aerosols by rainfall and as a result are not a significant component of changes in the surface radiation budget in our model. Article in Journal/Newspaper albedo Arctic Arctic Ocean Sea ice RePEc (Research Papers in Economics) Arctic Arctic Ocean
institution Open Polar
collection RePEc (Research Papers in Economics)
op_collection_id ftrepec
language unknown
description Abstract The progressive loss of Arctic sea ice leads to increased surface emissions of Dimethyl Sulphide (DMS), which is the dominant local source of sulphate aerosols. We test the hypothesis that cloud condensation nuclei, derived from DMS, will increase cloud-top albedo in an earth-system global climate model. The earth-system model includes fully interactive ocean biology, DMS, atmospheric chemistry, aerosols and cloud microphysics. In an idealised warming scenario, the Arctic Ocean becomes ice-free in summer when atmospheric CO2 is increased by 1 % per year to four times the pre-industrial concentrations. The summer boundary layer near-surface inversion strengthens, increasing stratification with warming, whilst the autumn inversion weakens. We find that the dominant change in cloud albedo arises from the conversion of summer clouds from ice to liquid, reducing the solar flux at the surface by 27 W m−2. Only 1–2 W m−2 of the reduced solar flux is attributed to cloud condensation nuclei associated with sulphate aerosols derived from the 2–5 fold increase in DMS emissions that results from an ice-free ocean. We conclude that aerosol-cloud feedbacks originating from DMS production in the Arctic region are largely mitigated through increased wet deposition of sulphate aerosols by rainfall and as a result are not a significant component of changes in the surface radiation budget in our model.
format Article in Journal/Newspaper
author J. K. Ridley
M. A. Ringer
R. M. Sheward
spellingShingle J. K. Ridley
M. A. Ringer
R. M. Sheward
The transformation of Arctic clouds with warming
author_facet J. K. Ridley
M. A. Ringer
R. M. Sheward
author_sort J. K. Ridley
title The transformation of Arctic clouds with warming
title_short The transformation of Arctic clouds with warming
title_full The transformation of Arctic clouds with warming
title_fullStr The transformation of Arctic clouds with warming
title_full_unstemmed The transformation of Arctic clouds with warming
title_sort transformation of arctic clouds with warming
url http://link.springer.com/10.1007/s10584-016-1772-4
geographic Arctic
Arctic Ocean
geographic_facet Arctic
Arctic Ocean
genre albedo
Arctic
Arctic Ocean
Sea ice
genre_facet albedo
Arctic
Arctic Ocean
Sea ice
op_relation http://link.springer.com/10.1007/s10584-016-1772-4
_version_ 1766244513531035648

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