Sensitivity of Tropospheric Chemical Composition to Halogen-Radical Chemistry Using a Fully Coupled Size-Resolved Multiphase Chemistry/Global Climate System: Halogen Distributions, Aerosol Composition, and Sensitivity of Climate-Relevant Gases

Observations and model calculations indicate that highly non-linear multiphase atmospheric processes involving inorganic Cl and Br significantly impact tropospheric chemistry and composition, aerosol evolution, and radiative transfer. The sensitivity of global atmospheric chemistry to the production...

Full description

Bibliographic Details
Main Authors: Long, M. S., Keene, W.C., Easter, R. C., Sander, R., Liu, Xiaohong, Kerkweg, A., Erickson, D.
Format: Other Non-Article Part of Journal/Newspaper
Language:English
Published: University of Wyoming. Libraries 2014
Subjects:
Engineering
Southern Ocean
Online Access:https://hdl.handle.net/20.500.11919/715
https://doi.org/10.5194/acpd-13-6067-2013
id ftcolostateunidc:oai:mountainscholar.org:20.500.11919/715
record_format openpolar
spelling ftcolostateunidc:oai:mountainscholar.org:20.500.11919/715 2023-05-15T18:26:00+02:00 Sensitivity of Tropospheric Chemical Composition to Halogen-Radical Chemistry Using a Fully Coupled Size-Resolved Multiphase Chemistry/Global Climate System: Halogen Distributions, Aerosol Composition, and Sensitivity of Climate-Relevant Gases Long, M. S. Keene, W.C. Easter, R. C. Sander, R. Liu, Xiaohong Kerkweg, A. Erickson, D. 2014-04-07 application/pdf https://hdl.handle.net/20.500.11919/715 https://doi.org/10.5194/acpd-13-6067-2013 English eng eng University of Wyoming. Libraries Faculty Publications - Atmospheric Science https://hdl.handle.net/20.500.11919/715 doi:10.5194/acpd-13-6067-2013 http://creativecommons.org/licenses/by/3.0/ CC-BY Atmospheric Science Faculty Publications Engineering Journal contribution 2014 ftcolostateunidc https://doi.org/20.500.11919/715 https://doi.org/10.5194/acpd-13-6067-2013 2021-07-14T20:51:02Z Observations and model calculations indicate that highly non-linear multiphase atmospheric processes involving inorganic Cl and Br significantly impact tropospheric chemistry and composition, aerosol evolution, and radiative transfer. The sensitivity of global atmospheric chemistry to the production of marine aerosol and the associated activation and cycling of inorganic Cl and Br was investigated using a size-resolved multiphase coupled chemistry–global climate model (National Center for Atmospheric Research's Community Atmosphere Model (CAM) v3.6.33). Simulated results revealed strong meridional and vertical gradients in Cl and Br species. They also point to possible physicochemical mechanisms that may account for several previously unexplained phenomena, including the enrichment of Br− in submicron aerosol and the presence of a BrO maximum in the polar free troposphere. However, simulated total volatile inorganic Br mixing ratios in the troposphere were generally higher than observed, due in part to the overly efficient net production of BrCl. In addition, the emission scheme for marine aerosol and associated Br−, which is the only source for Br in the model, overestimates emission fluxes from the high-latitude Southern Ocean. Br in the stratosphere was lower than observed due to the lack of long-lived precursor organobromine species in the simulation. Comparing simulations using chemical mechanisms with and without reactive Cl and Br species demonstrates a significant temporal and spatial sensitivity of primary atmospheric oxidants (O3, HOx, NOx), CH4, non-methane hydrocarbons (NMHCs), and dimethyl sulfide (DMS) to halogen cycling. Globally, halogen chemistry had relatively less impact on SO2 and non-sea-salt (nss) SO2−4 although significant regional differences were evident. Although variable geographically, much of this sensitivity is attributable to either over-vigorous activation of Br (primarily BrCl) via the chemical mechanism or overproduction of sea-salt aerosol simulated under higher-wind regimes. In regions where simulated mixing ratios of reactive Br and Cl fell within observed ranges, though, halogen chemistry drove large changes in oxidant fields and associated chemical processes relative to simulations with no halogens. However, the overall simulated impacts of Br chemistry globally are overestimated and thus caution is warranted in their interpretation. Other Non-Article Part of Journal/Newspaper Southern Ocean Digital Collections of Colorado (Colorado State University) Southern Ocean
institution Open Polar
collection Digital Collections of Colorado (Colorado State University)
op_collection_id ftcolostateunidc
language English
topic Engineering
spellingShingle Engineering
Long, M. S.
Keene, W.C.
Easter, R. C.
Sander, R.
Liu, Xiaohong
Kerkweg, A.
Erickson, D.
Sensitivity of Tropospheric Chemical Composition to Halogen-Radical Chemistry Using a Fully Coupled Size-Resolved Multiphase Chemistry/Global Climate System: Halogen Distributions, Aerosol Composition, and Sensitivity of Climate-Relevant Gases
topic_facet Engineering
description Observations and model calculations indicate that highly non-linear multiphase atmospheric processes involving inorganic Cl and Br significantly impact tropospheric chemistry and composition, aerosol evolution, and radiative transfer. The sensitivity of global atmospheric chemistry to the production of marine aerosol and the associated activation and cycling of inorganic Cl and Br was investigated using a size-resolved multiphase coupled chemistry–global climate model (National Center for Atmospheric Research's Community Atmosphere Model (CAM) v3.6.33). Simulated results revealed strong meridional and vertical gradients in Cl and Br species. They also point to possible physicochemical mechanisms that may account for several previously unexplained phenomena, including the enrichment of Br− in submicron aerosol and the presence of a BrO maximum in the polar free troposphere. However, simulated total volatile inorganic Br mixing ratios in the troposphere were generally higher than observed, due in part to the overly efficient net production of BrCl. In addition, the emission scheme for marine aerosol and associated Br−, which is the only source for Br in the model, overestimates emission fluxes from the high-latitude Southern Ocean. Br in the stratosphere was lower than observed due to the lack of long-lived precursor organobromine species in the simulation. Comparing simulations using chemical mechanisms with and without reactive Cl and Br species demonstrates a significant temporal and spatial sensitivity of primary atmospheric oxidants (O3, HOx, NOx), CH4, non-methane hydrocarbons (NMHCs), and dimethyl sulfide (DMS) to halogen cycling. Globally, halogen chemistry had relatively less impact on SO2 and non-sea-salt (nss) SO2−4 although significant regional differences were evident. Although variable geographically, much of this sensitivity is attributable to either over-vigorous activation of Br (primarily BrCl) via the chemical mechanism or overproduction of sea-salt aerosol simulated under higher-wind regimes. In regions where simulated mixing ratios of reactive Br and Cl fell within observed ranges, though, halogen chemistry drove large changes in oxidant fields and associated chemical processes relative to simulations with no halogens. However, the overall simulated impacts of Br chemistry globally are overestimated and thus caution is warranted in their interpretation.
format Other Non-Article Part of Journal/Newspaper
author Long, M. S.
Keene, W.C.
Easter, R. C.
Sander, R.
Liu, Xiaohong
Kerkweg, A.
Erickson, D.
author_facet Long, M. S.
Keene, W.C.
Easter, R. C.
Sander, R.
Liu, Xiaohong
Kerkweg, A.
Erickson, D.
author_sort Long, M. S.
title Sensitivity of Tropospheric Chemical Composition to Halogen-Radical Chemistry Using a Fully Coupled Size-Resolved Multiphase Chemistry/Global Climate System: Halogen Distributions, Aerosol Composition, and Sensitivity of Climate-Relevant Gases
title_short Sensitivity of Tropospheric Chemical Composition to Halogen-Radical Chemistry Using a Fully Coupled Size-Resolved Multiphase Chemistry/Global Climate System: Halogen Distributions, Aerosol Composition, and Sensitivity of Climate-Relevant Gases
title_full Sensitivity of Tropospheric Chemical Composition to Halogen-Radical Chemistry Using a Fully Coupled Size-Resolved Multiphase Chemistry/Global Climate System: Halogen Distributions, Aerosol Composition, and Sensitivity of Climate-Relevant Gases
title_fullStr Sensitivity of Tropospheric Chemical Composition to Halogen-Radical Chemistry Using a Fully Coupled Size-Resolved Multiphase Chemistry/Global Climate System: Halogen Distributions, Aerosol Composition, and Sensitivity of Climate-Relevant Gases
title_full_unstemmed Sensitivity of Tropospheric Chemical Composition to Halogen-Radical Chemistry Using a Fully Coupled Size-Resolved Multiphase Chemistry/Global Climate System: Halogen Distributions, Aerosol Composition, and Sensitivity of Climate-Relevant Gases
title_sort sensitivity of tropospheric chemical composition to halogen-radical chemistry using a fully coupled size-resolved multiphase chemistry/global climate system: halogen distributions, aerosol composition, and sensitivity of climate-relevant gases
publisher University of Wyoming. Libraries
publishDate 2014
url https://hdl.handle.net/20.500.11919/715
https://doi.org/10.5194/acpd-13-6067-2013
geographic Southern Ocean
geographic_facet Southern Ocean
genre Southern Ocean
genre_facet Southern Ocean
op_source Atmospheric Science Faculty Publications
op_relation Faculty Publications - Atmospheric Science
https://hdl.handle.net/20.500.11919/715
doi:10.5194/acpd-13-6067-2013
op_rights http://creativecommons.org/licenses/by/3.0/
op_rightsnorm CC-BY
op_doi https://doi.org/20.500.11919/715
https://doi.org/10.5194/acpd-13-6067-2013
_version_ 1766207768330502144

Similar Items