The Specified Chemistry Whole Atmosphere Community Climate Model (SC-WACCM)

We here present, document and validate a new atmospheric component of the Community Earth System Model (CESM1): the Specified Chemistry Whole Atmosphere Community Climate Model (SC-WACCM). As the name implies, SC-WACCM is a middle atmosphere-resolving model with prescribed, rather than interactive c...

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Main Authors: Smith, Karen L., Neely, R. R., Marsh, D. R., Polvani, Lorenzo M.
Format: Article in Journal/Newspaper
Language:English
Published: 2014
Subjects:
Atmospheric ozone
Atmospheric chemistry
Climatic changes > Mathematical models
Ozone layer
Climatic changes > Simulation methods
Climatic changes > Forecasting
Ozone layer depletion
Climatology
Sea ice
Online Access:https://doi.org/10.7916/D8DF6R2H
id ftcolumbiauniv:oai:academiccommons.columbia.edu:10.7916/D8DF6R2H
record_format openpolar
spelling ftcolumbiauniv:oai:academiccommons.columbia.edu:10.7916/D8DF6R2H 2023-05-15T18:18:49+02:00 The Specified Chemistry Whole Atmosphere Community Climate Model (SC-WACCM) Smith, Karen L. Neely, R. R. Marsh, D. R. Polvani, Lorenzo M. 2014 https://doi.org/10.7916/D8DF6R2H English eng https://doi.org/10.7916/D8DF6R2H Atmospheric ozone Atmospheric chemistry Climatic changes--Mathematical models Ozone layer Climatic changes--Simulation methods Climatic changes--Forecasting Ozone layer depletion Climatology articles 2014 ftcolumbiauniv https://doi.org/10.7916/D8DF6R2H 2019-04-04T08:14:12Z We here present, document and validate a new atmospheric component of the Community Earth System Model (CESM1): the Specified Chemistry Whole Atmosphere Community Climate Model (SC-WACCM). As the name implies, SC-WACCM is a middle atmosphere-resolving model with prescribed, rather than interactive chemistry. Ozone concentrations are specified throughout the atmosphere, using zonal and monthly mean climatologies computed by a companion integration with the Whole Atmosphere Community Climate Model (WACCM). Above 65 km, in addition, the climatological chemical and shortwave heating, nitrogen oxide, atomic and molecular oxygen and carbon dioxide are also prescribed from the companion WACCM integration. We carefully compare the climatology and the climate variability of preindustrial integrations of SC-WACCM and WACCM each coupled with active land, ocean and sea-ice components. We note some differences in upper stratospheric and lower mesospheric temperature, just below the 65 km transition level, due to the diurnal ozone cycle that is not captured when monthly mean ozone is used. Nonetheless, we find that the climatology and variability of the stratosphere, the troposphere and surface climate are nearly identical in SC-WACCM and WACCM. Notably, the frequency and amplitude of Northern Hemisphere stratospheric sudden warmings in the two integrations are not significantly different. Also, we compare WACCM and SC-WACCM to CCSM4, the “low-top” version of CESM1, and we find very significant differences in the stratospheric climatology and variability. The removal of the chemistry reduces the computational cost of SC-WACCM to approximately one half of WACCM: in fact, SC-WACCM is only 2.5 times more expensive than CCSM4 at the same horizontal resolution. This considerable reduction in computational cost makes the new SC-WACCM component of CESM1 ideally suited for studies of stratosphere-troposphere dynamical coupling and, more generally, the role of the stratosphere in the climate system. Article in Journal/Newspaper Sea ice Columbia University: Academic Commons
institution Open Polar
collection Columbia University: Academic Commons
op_collection_id ftcolumbiauniv
language English
topic Atmospheric ozone
Atmospheric chemistry
Climatic changes--Mathematical models
Ozone layer
Climatic changes--Simulation methods
Climatic changes--Forecasting
Ozone layer depletion
Climatology
spellingShingle Atmospheric ozone
Atmospheric chemistry
Climatic changes--Mathematical models
Ozone layer
Climatic changes--Simulation methods
Climatic changes--Forecasting
Ozone layer depletion
Climatology
Smith, Karen L.
Neely, R. R.
Marsh, D. R.
Polvani, Lorenzo M.
The Specified Chemistry Whole Atmosphere Community Climate Model (SC-WACCM)
topic_facet Atmospheric ozone
Atmospheric chemistry
Climatic changes--Mathematical models
Ozone layer
Climatic changes--Simulation methods
Climatic changes--Forecasting
Ozone layer depletion
Climatology
description We here present, document and validate a new atmospheric component of the Community Earth System Model (CESM1): the Specified Chemistry Whole Atmosphere Community Climate Model (SC-WACCM). As the name implies, SC-WACCM is a middle atmosphere-resolving model with prescribed, rather than interactive chemistry. Ozone concentrations are specified throughout the atmosphere, using zonal and monthly mean climatologies computed by a companion integration with the Whole Atmosphere Community Climate Model (WACCM). Above 65 km, in addition, the climatological chemical and shortwave heating, nitrogen oxide, atomic and molecular oxygen and carbon dioxide are also prescribed from the companion WACCM integration. We carefully compare the climatology and the climate variability of preindustrial integrations of SC-WACCM and WACCM each coupled with active land, ocean and sea-ice components. We note some differences in upper stratospheric and lower mesospheric temperature, just below the 65 km transition level, due to the diurnal ozone cycle that is not captured when monthly mean ozone is used. Nonetheless, we find that the climatology and variability of the stratosphere, the troposphere and surface climate are nearly identical in SC-WACCM and WACCM. Notably, the frequency and amplitude of Northern Hemisphere stratospheric sudden warmings in the two integrations are not significantly different. Also, we compare WACCM and SC-WACCM to CCSM4, the “low-top” version of CESM1, and we find very significant differences in the stratospheric climatology and variability. The removal of the chemistry reduces the computational cost of SC-WACCM to approximately one half of WACCM: in fact, SC-WACCM is only 2.5 times more expensive than CCSM4 at the same horizontal resolution. This considerable reduction in computational cost makes the new SC-WACCM component of CESM1 ideally suited for studies of stratosphere-troposphere dynamical coupling and, more generally, the role of the stratosphere in the climate system.
format Article in Journal/Newspaper
author Smith, Karen L.
Neely, R. R.
Marsh, D. R.
Polvani, Lorenzo M.
author_facet Smith, Karen L.
Neely, R. R.
Marsh, D. R.
Polvani, Lorenzo M.
author_sort Smith, Karen L.
title The Specified Chemistry Whole Atmosphere Community Climate Model (SC-WACCM)
title_short The Specified Chemistry Whole Atmosphere Community Climate Model (SC-WACCM)
title_full The Specified Chemistry Whole Atmosphere Community Climate Model (SC-WACCM)
title_fullStr The Specified Chemistry Whole Atmosphere Community Climate Model (SC-WACCM)
title_full_unstemmed The Specified Chemistry Whole Atmosphere Community Climate Model (SC-WACCM)
title_sort specified chemistry whole atmosphere community climate model (sc-waccm)
publishDate 2014
url https://doi.org/10.7916/D8DF6R2H
genre Sea ice
genre_facet Sea ice
op_relation https://doi.org/10.7916/D8DF6R2H
op_doi https://doi.org/10.7916/D8DF6R2H
_version_ 1766195540308000768

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