Surface ozone variations at the Great Wall Station, Antarctica during austral summer

Surface ozone (O3) is a secondary pollutant harmful to human health and a greenhouse gas which is one of the prime climate forcers. Due to the clean atmospheric environment of the Antarctic region and given the complexity of O3 chemistry, the observation of surface O3 variability in this region is n...

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Main Authors: Sentian, Justin, Herman, Franky, Mohd Nadzir, Mohd Sharul, Wan Yee, Vivian Kong
Format: Article in Journal/Newspaper
Language:English
Published: Polar Research Institute of China - PRIC 2020
Subjects:
Atmosphere
Antarctic
The Antarctic
Austral
Great Wall Station
Advances in Polar Science
Antarc*
Antarctica
Polar Science
Online Access:http://library.arcticportal.org/2718/
http://library.arcticportal.org/2718/1/A2002002.pdf
id ftarcticportal:oai:generic.eprints.org:2718
record_format openpolar
spelling ftarcticportal:oai:generic.eprints.org:2718 2023-12-10T09:39:00+01:00 Surface ozone variations at the Great Wall Station, Antarctica during austral summer Sentian, Justin Herman, Franky Mohd Nadzir, Mohd Sharul Wan Yee, Vivian Kong 2020-06 application/pdf http://library.arcticportal.org/2718/ http://library.arcticportal.org/2718/1/A2002002.pdf en eng Polar Research Institute of China - PRIC http://library.arcticportal.org/2718/1/A2002002.pdf Sentian, Justin and Herman, Franky and Mohd Nadzir, Mohd Sharul and Wan Yee, Vivian Kong (2020) Surface ozone variations at the Great Wall Station, Antarctica during austral summer. Advances in Polar Science, 31 (2). pp. 92-102. Atmosphere Article PeerReviewed 2020 ftarcticportal 2023-11-15T23:54:41Z Surface ozone (O3) is a secondary pollutant harmful to human health and a greenhouse gas which is one of the prime climate forcers. Due to the clean atmospheric environment of the Antarctic region and given the complexity of O3 chemistry, the observation of surface O3 variability in this region is necessary in the quest to better understand the potential sources and sink of polar surface O3. In this paper, we highlighted our observations on O3 variability at the Great Wall Station (GWS) during austral summer in December 2018 and January 2019. The continuous surface O3 measurement at the GWS, Antarctica was carried out using the Ecotech Ozone analyzer. To understand the roles of the meteorological conditions on the temporal variations of O3, meteorological data was obtained from the conventional auto-observational station at the GWS. The Hybrid Single-Particle Lagrangian Integrated Trajectory (HYSPLIT) model was employed to investigate the air mass transport over the region. The observed austral summer surface O3 concentrations at the GWS exhibited variability and were significantly lower than those previously observed at other permanent coastal stations in Antarctica. The surface ozone variability at the GWS was strongly influenced by the synoptic change of air mass origin although the roles of photochemistry production and destruction were still uncertain. Marine characteristics and stable surface O3 characterized the air masses that reached the GWS. The unique characteristic of surface O3 at the coastal site of GWS was emphasized by its synoptic air mass characteristics, which displayed a significant influence on surface O3 variability. Air mass that traveled over the ocean with relatively shorter distance was linked to the lower O3 level, whereby the marine transport of reactive bromine (Br) species was thought to play a significant role in the tropospheric chemistry that leads to O3 destruction. Meanwhile, the diurnal variation indicated that the O3 background concentration levels were not strongly ... Article in Journal/Newspaper Advances in Polar Science Antarc* Antarctic Antarctica Polar Science Polar Science Arctic Portal Library Antarctic The Antarctic Austral Great Wall Station ENVELOPE(-58.970,-58.970,-62.217,-62.217)
institution Open Polar
collection Arctic Portal Library
op_collection_id ftarcticportal
language English
topic Atmosphere
spellingShingle Atmosphere
Sentian, Justin
Herman, Franky
Mohd Nadzir, Mohd Sharul
Wan Yee, Vivian Kong
Surface ozone variations at the Great Wall Station, Antarctica during austral summer
topic_facet Atmosphere
description Surface ozone (O3) is a secondary pollutant harmful to human health and a greenhouse gas which is one of the prime climate forcers. Due to the clean atmospheric environment of the Antarctic region and given the complexity of O3 chemistry, the observation of surface O3 variability in this region is necessary in the quest to better understand the potential sources and sink of polar surface O3. In this paper, we highlighted our observations on O3 variability at the Great Wall Station (GWS) during austral summer in December 2018 and January 2019. The continuous surface O3 measurement at the GWS, Antarctica was carried out using the Ecotech Ozone analyzer. To understand the roles of the meteorological conditions on the temporal variations of O3, meteorological data was obtained from the conventional auto-observational station at the GWS. The Hybrid Single-Particle Lagrangian Integrated Trajectory (HYSPLIT) model was employed to investigate the air mass transport over the region. The observed austral summer surface O3 concentrations at the GWS exhibited variability and were significantly lower than those previously observed at other permanent coastal stations in Antarctica. The surface ozone variability at the GWS was strongly influenced by the synoptic change of air mass origin although the roles of photochemistry production and destruction were still uncertain. Marine characteristics and stable surface O3 characterized the air masses that reached the GWS. The unique characteristic of surface O3 at the coastal site of GWS was emphasized by its synoptic air mass characteristics, which displayed a significant influence on surface O3 variability. Air mass that traveled over the ocean with relatively shorter distance was linked to the lower O3 level, whereby the marine transport of reactive bromine (Br) species was thought to play a significant role in the tropospheric chemistry that leads to O3 destruction. Meanwhile, the diurnal variation indicated that the O3 background concentration levels were not strongly ...
format Article in Journal/Newspaper
author Sentian, Justin
Herman, Franky
Mohd Nadzir, Mohd Sharul
Wan Yee, Vivian Kong
author_facet Sentian, Justin
Herman, Franky
Mohd Nadzir, Mohd Sharul
Wan Yee, Vivian Kong
author_sort Sentian, Justin
title Surface ozone variations at the Great Wall Station, Antarctica during austral summer
title_short Surface ozone variations at the Great Wall Station, Antarctica during austral summer
title_full Surface ozone variations at the Great Wall Station, Antarctica during austral summer
title_fullStr Surface ozone variations at the Great Wall Station, Antarctica during austral summer
title_full_unstemmed Surface ozone variations at the Great Wall Station, Antarctica during austral summer
title_sort surface ozone variations at the great wall station, antarctica during austral summer
publisher Polar Research Institute of China - PRIC
publishDate 2020
url http://library.arcticportal.org/2718/
http://library.arcticportal.org/2718/1/A2002002.pdf
long_lat ENVELOPE(-58.970,-58.970,-62.217,-62.217)
geographic Antarctic
The Antarctic
Austral
Great Wall Station
geographic_facet Antarctic
The Antarctic
Austral
Great Wall Station
genre Advances in Polar Science
Antarc*
Antarctic
Antarctica
Polar Science
Polar Science
genre_facet Advances in Polar Science
Antarc*
Antarctic
Antarctica
Polar Science
Polar Science
op_relation http://library.arcticportal.org/2718/1/A2002002.pdf
Sentian, Justin and Herman, Franky and Mohd Nadzir, Mohd Sharul and Wan Yee, Vivian Kong (2020) Surface ozone variations at the Great Wall Station, Antarctica during austral summer. Advances in Polar Science, 31 (2). pp. 92-102.
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