Springtime photochemistry at northern mid and high latitudes

Physical and chemical properties of the atmosphere at 0-8 km were measured during the Tropospheric Ozone Production about the Spring Equinox (TOPSE) experiments from February to May 2000 at mid (40°-60°N) and high latitudes (60°-80°N). The observations were analyzed using a diet steady state box mod...

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Main Authors: Wang, Yuhang, Ridley, Brian, Fried, Alan, Cantrell, Christopher, Davis, Douglas, Chen, Gao, Snow, Julie, Heikes, Brian, Talbot, Robert, Dibb, Jack, Flocke, Frank, Weinheimer, Andrew, Blake, Nicola, Blake, Donald, Shetter, Richard, Lefer, Barry, Atlas, Elliot, Coffey, Michael, Walega, Jim, Wert, Brian
Format: Article in Journal/Newspaper
Language:unknown
Published: eScholarship, University of California 2003
Subjects:
Earth Sciences
Atmospheric Sciences
springtime
ozone
HOx
oxidation
reactive nitrogen
Meteorology & Atmospheric Sciences
Tropospheric Ozone Production About the Spring Equinox
Online Access:https://escholarship.org/uc/item/6q08n212
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record_format openpolar
spelling ftcdlib:oai:escholarship.org:ark:/13030/qt6q08n212 2023-10-25T01:44:24+02:00 Springtime photochemistry at northern mid and high latitudes Wang, Yuhang Ridley, Brian Fried, Alan Cantrell, Christopher Davis, Douglas Chen, Gao Snow, Julie Heikes, Brian Talbot, Robert Dibb, Jack Flocke, Frank Weinheimer, Andrew Blake, Nicola Blake, Donald Shetter, Richard Lefer, Barry Atlas, Elliot Coffey, Michael Walega, Jim Wert, Brian 2003-01-01 application/pdf https://escholarship.org/uc/item/6q08n212 unknown eScholarship, University of California qt6q08n212 https://escholarship.org/uc/item/6q08n212 CC-BY Journal of Geophysical Research, vol 108, iss D4 Earth Sciences Atmospheric Sciences springtime ozone HOx oxidation reactive nitrogen Meteorology & Atmospheric Sciences article 2003 ftcdlib 2023-09-25T18:03:03Z Physical and chemical properties of the atmosphere at 0-8 km were measured during the Tropospheric Ozone Production about the Spring Equinox (TOPSE) experiments from February to May 2000 at mid (40°-60°N) and high latitudes (60°-80°N). The observations were analyzed using a diet steady state box model to examine HOx and O3 photochemistry during the spring transition period. The radical chemistry is driven primarily by photolysis of O3 and the subsequent reaction of O(1D) and H2O, the rate of which increases rapidly during spring. Unlike in other tropospheric experiments, observed H2O2 concentrations are a factor of 2-10 lower than those simulated by the model. The required scavenging timescale to reconcile the model overestimates shows a rapid seasonal decrease down to 0.5-1 day in May, which cannot be explained by known mechanisms. This loss of H2O2 implies a large loss of HOx resulting in decreases in O3 production (10-20%) and OH concentrations (20-30%). Photolysis of CH2O, either transported into the region or produced by unknown chemical pathways, appears to provide a significant HOx source at 6-8 km at high latitudes. The rapid increase of in situ O3 production in spring is fueled by concurrent increases of the primary HOx production and NO concentrations. Long-lived reactive nitrogen species continue to accumulate at mid and high latitudes in spring. There is a net loss of NOx to HNO3 and PAN throughout the spring, suggesting that these long-term NOx reservoirs do not provide a net source for NOx in the region. In Situ O3 chemical loss is dominated by the reaction of O3 and HO2, and not that of O(1D) and H2O. At midlatitudes, there is net in situ chemical production Of O3 from February to May. The lower free troposphere (1-4 km) is a region of significant net O3 production. The net production peaks in April coinciding with the observed peak of column O3 (0-8 km). The net in situ O3 production at midlatitudes can explain much of the observed column O3 increase, although it alone cannot explain the observed ... Article in Journal/Newspaper Tropospheric Ozone Production About the Spring Equinox University of California: eScholarship
institution Open Polar
collection University of California: eScholarship
op_collection_id ftcdlib
language unknown
topic Earth Sciences
Atmospheric Sciences
springtime
ozone
HOx
oxidation
reactive nitrogen
Meteorology & Atmospheric Sciences
spellingShingle Earth Sciences
Atmospheric Sciences
springtime
ozone
HOx
oxidation
reactive nitrogen
Meteorology & Atmospheric Sciences
Wang, Yuhang
Ridley, Brian
Fried, Alan
Cantrell, Christopher
Davis, Douglas
Chen, Gao
Snow, Julie
Heikes, Brian
Talbot, Robert
Dibb, Jack
Flocke, Frank
Weinheimer, Andrew
Blake, Nicola
Blake, Donald
Shetter, Richard
Lefer, Barry
Atlas, Elliot
Coffey, Michael
Walega, Jim
Wert, Brian
Springtime photochemistry at northern mid and high latitudes
topic_facet Earth Sciences
Atmospheric Sciences
springtime
ozone
HOx
oxidation
reactive nitrogen
Meteorology & Atmospheric Sciences
description Physical and chemical properties of the atmosphere at 0-8 km were measured during the Tropospheric Ozone Production about the Spring Equinox (TOPSE) experiments from February to May 2000 at mid (40°-60°N) and high latitudes (60°-80°N). The observations were analyzed using a diet steady state box model to examine HOx and O3 photochemistry during the spring transition period. The radical chemistry is driven primarily by photolysis of O3 and the subsequent reaction of O(1D) and H2O, the rate of which increases rapidly during spring. Unlike in other tropospheric experiments, observed H2O2 concentrations are a factor of 2-10 lower than those simulated by the model. The required scavenging timescale to reconcile the model overestimates shows a rapid seasonal decrease down to 0.5-1 day in May, which cannot be explained by known mechanisms. This loss of H2O2 implies a large loss of HOx resulting in decreases in O3 production (10-20%) and OH concentrations (20-30%). Photolysis of CH2O, either transported into the region or produced by unknown chemical pathways, appears to provide a significant HOx source at 6-8 km at high latitudes. The rapid increase of in situ O3 production in spring is fueled by concurrent increases of the primary HOx production and NO concentrations. Long-lived reactive nitrogen species continue to accumulate at mid and high latitudes in spring. There is a net loss of NOx to HNO3 and PAN throughout the spring, suggesting that these long-term NOx reservoirs do not provide a net source for NOx in the region. In Situ O3 chemical loss is dominated by the reaction of O3 and HO2, and not that of O(1D) and H2O. At midlatitudes, there is net in situ chemical production Of O3 from February to May. The lower free troposphere (1-4 km) is a region of significant net O3 production. The net production peaks in April coinciding with the observed peak of column O3 (0-8 km). The net in situ O3 production at midlatitudes can explain much of the observed column O3 increase, although it alone cannot explain the observed ...
format Article in Journal/Newspaper
author Wang, Yuhang
Ridley, Brian
Fried, Alan
Cantrell, Christopher
Davis, Douglas
Chen, Gao
Snow, Julie
Heikes, Brian
Talbot, Robert
Dibb, Jack
Flocke, Frank
Weinheimer, Andrew
Blake, Nicola
Blake, Donald
Shetter, Richard
Lefer, Barry
Atlas, Elliot
Coffey, Michael
Walega, Jim
Wert, Brian
author_facet Wang, Yuhang
Ridley, Brian
Fried, Alan
Cantrell, Christopher
Davis, Douglas
Chen, Gao
Snow, Julie
Heikes, Brian
Talbot, Robert
Dibb, Jack
Flocke, Frank
Weinheimer, Andrew
Blake, Nicola
Blake, Donald
Shetter, Richard
Lefer, Barry
Atlas, Elliot
Coffey, Michael
Walega, Jim
Wert, Brian
author_sort Wang, Yuhang
title Springtime photochemistry at northern mid and high latitudes
title_short Springtime photochemistry at northern mid and high latitudes
title_full Springtime photochemistry at northern mid and high latitudes
title_fullStr Springtime photochemistry at northern mid and high latitudes
title_full_unstemmed Springtime photochemistry at northern mid and high latitudes
title_sort springtime photochemistry at northern mid and high latitudes
publisher eScholarship, University of California
publishDate 2003
url https://escholarship.org/uc/item/6q08n212
genre Tropospheric Ozone Production About the Spring Equinox
genre_facet Tropospheric Ozone Production About the Spring Equinox
op_source Journal of Geophysical Research, vol 108, iss D4
op_relation qt6q08n212
https://escholarship.org/uc/item/6q08n212
op_rights CC-BY
_version_ 1780741938814648320

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