Relating large-scale subsidence to convection development in Arctic mixed-phase marine stratocumulus

Large-scale subsidence, associated with high-pressure systems, is often imposed in large-eddy simulation (LES) models to maintain the height of boundary layer (BL) clouds. Previous studies have considered the influence of subsidence on warm liquid clouds in subtropical regions; however, the relation...

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Published in:	Atmospheric Chemistry and Physics
Main Authors:	Young, Gillian, Connolly, Paul J., Dearden, Christopher, Choularton, Thomas W.
Format:	Text
Language:	English
Published:	2018
Subjects:	Arctic
Online Access:	https://doi.org/10.5194/acp-18-1475-2018 https://www.atmos-chem-phys.net/18/1475/2018/

id	ftcopernicus:oai:publications.copernicus.org:acp59963
record_format	openpolar
spelling	ftcopernicus:oai:publications.copernicus.org:acp59963 2023-05-15T14:58:04+02:00 Relating large-scale subsidence to convection development in Arctic mixed-phase marine stratocumulus Young, Gillian Connolly, Paul J. Dearden, Christopher Choularton, Thomas W. 2018-09-16 application/pdf https://doi.org/10.5194/acp-18-1475-2018 https://www.atmos-chem-phys.net/18/1475/2018/ eng eng doi:10.5194/acp-18-1475-2018 https://www.atmos-chem-phys.net/18/1475/2018/ eISSN: 1680-7324 Text 2018 ftcopernicus https://doi.org/10.5194/acp-18-1475-2018 2019-12-24T09:50:39Z Large-scale subsidence, associated with high-pressure systems, is often imposed in large-eddy simulation (LES) models to maintain the height of boundary layer (BL) clouds. Previous studies have considered the influence of subsidence on warm liquid clouds in subtropical regions; however, the relationship between subsidence and mixed-phase cloud microphysics has not specifically been studied. For the first time, we investigate how widespread subsidence associated with synoptic-scale meteorological features can affect the microphysics of Arctic mixed-phase marine stratocumulus (Sc) clouds. Modelled with LES, four idealised scenarios – a stable Sc, varied droplet ( N drop ) or ice ( N ice ) number concentrations, and a warming surface (representing motion southwards) – were subjected to different levels of subsidence to investigate the cloud microphysical response. We find strong sensitivities to large-scale subsidence, indicating that high-pressure systems in the ocean-exposed Arctic regions have the potential to generate turbulence and changes in cloud microphysics in any resident BL mixed-phase clouds. Increased cloud convection is modelled with increased subsidence, driven by longwave radiative cooling at cloud top and rain evaporative cooling and latent heating from snow growth below cloud. Subsidence strengthens the BL temperature inversion, thus reducing entrainment and allowing the liquid- and ice-water paths (LWPs, IWPs) to increase. Through increased cloud-top radiative cooling and subsequent convective overturning, precipitation production is enhanced: rain particle number concentrations ( N rain ), in-cloud rain mass production rates, and below-cloud evaporation rates increase with increased subsidence. Ice number concentrations ( N ice ) play an important role, as greater concentrations suppress the liquid phase; therefore, N ice acts to mediate the strength of turbulent overturning promoted by increased subsidence. With a warming surface, a lack of – or low – subsidence allows for rapid BL turbulent kinetic energy (TKE) coupling, leading to a heterogeneous cloud layer, cloud-top ascent, and cumuli formation below the Sc cloud. In these scenarios, higher levels of subsidence act to stabilise the Sc layer, where the combination of these two forcings counteract one another to produce a stable, yet dynamic, cloud layer. Text Arctic Copernicus Publications: E-Journals Arctic Atmospheric Chemistry and Physics 18 3 1475 1494
institution	Open Polar
collection	Copernicus Publications: E-Journals
op_collection_id	ftcopernicus
language	English
description	Large-scale subsidence, associated with high-pressure systems, is often imposed in large-eddy simulation (LES) models to maintain the height of boundary layer (BL) clouds. Previous studies have considered the influence of subsidence on warm liquid clouds in subtropical regions; however, the relationship between subsidence and mixed-phase cloud microphysics has not specifically been studied. For the first time, we investigate how widespread subsidence associated with synoptic-scale meteorological features can affect the microphysics of Arctic mixed-phase marine stratocumulus (Sc) clouds. Modelled with LES, four idealised scenarios – a stable Sc, varied droplet ( N drop ) or ice ( N ice ) number concentrations, and a warming surface (representing motion southwards) – were subjected to different levels of subsidence to investigate the cloud microphysical response. We find strong sensitivities to large-scale subsidence, indicating that high-pressure systems in the ocean-exposed Arctic regions have the potential to generate turbulence and changes in cloud microphysics in any resident BL mixed-phase clouds. Increased cloud convection is modelled with increased subsidence, driven by longwave radiative cooling at cloud top and rain evaporative cooling and latent heating from snow growth below cloud. Subsidence strengthens the BL temperature inversion, thus reducing entrainment and allowing the liquid- and ice-water paths (LWPs, IWPs) to increase. Through increased cloud-top radiative cooling and subsequent convective overturning, precipitation production is enhanced: rain particle number concentrations ( N rain ), in-cloud rain mass production rates, and below-cloud evaporation rates increase with increased subsidence. Ice number concentrations ( N ice ) play an important role, as greater concentrations suppress the liquid phase; therefore, N ice acts to mediate the strength of turbulent overturning promoted by increased subsidence. With a warming surface, a lack of – or low – subsidence allows for rapid BL turbulent kinetic energy (TKE) coupling, leading to a heterogeneous cloud layer, cloud-top ascent, and cumuli formation below the Sc cloud. In these scenarios, higher levels of subsidence act to stabilise the Sc layer, where the combination of these two forcings counteract one another to produce a stable, yet dynamic, cloud layer.
format	Text
author	Young, Gillian Connolly, Paul J. Dearden, Christopher Choularton, Thomas W.
spellingShingle	Young, Gillian Connolly, Paul J. Dearden, Christopher Choularton, Thomas W. Relating large-scale subsidence to convection development in Arctic mixed-phase marine stratocumulus
author_facet	Young, Gillian Connolly, Paul J. Dearden, Christopher Choularton, Thomas W.
author_sort	Young, Gillian
title	Relating large-scale subsidence to convection development in Arctic mixed-phase marine stratocumulus
title_short	Relating large-scale subsidence to convection development in Arctic mixed-phase marine stratocumulus
title_full	Relating large-scale subsidence to convection development in Arctic mixed-phase marine stratocumulus
title_fullStr	Relating large-scale subsidence to convection development in Arctic mixed-phase marine stratocumulus
title_full_unstemmed	Relating large-scale subsidence to convection development in Arctic mixed-phase marine stratocumulus
title_sort	relating large-scale subsidence to convection development in arctic mixed-phase marine stratocumulus
publishDate	2018
url	https://doi.org/10.5194/acp-18-1475-2018 https://www.atmos-chem-phys.net/18/1475/2018/
geographic	Arctic
geographic_facet	Arctic
genre	Arctic
genre_facet	Arctic
op_source	eISSN: 1680-7324
op_relation	doi:10.5194/acp-18-1475-2018 https://www.atmos-chem-phys.net/18/1475/2018/
op_doi	https://doi.org/10.5194/acp-18-1475-2018
container_title	Atmospheric Chemistry and Physics
container_volume	18
container_issue	3
container_start_page	1475
op_container_end_page	1494
_version_	1766330161762926592

Relating large-scale subsidence to convection development in Arctic mixed-phase marine stratocumulus

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