Spatial-temporal variations in surface ozone over Ushuaia and the Antarctic region: observations from in situ measurements, satellite data, and global models

The Antarctic continent is known to be an unpopulated region due to its extreme weather and climate conditions. However, the air quality over this continent can be affected by long-lived anthropogenic pollutants from the mainland. The Argentinian region of Ushuaia is often the main source area of ac...

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Main Authors: Mohd Shahrul, Mohd Nadzir, Ashfold, Matthew J., Md Firoz, Khan, Robinson, Andrew D., Aazani, Mujahid
Format: Article in Journal/Newspaper
Language:English
Published: Springer Verlag 2018
Subjects:
GC Oceanography
GE Environmental Sciences
Antarctic
The Antarctic
Antarctic Peninsula
Drake Passage
South Pole
Ushuaia
Antarc*
South pole
Online Access:http://ir.unimas.my/id/eprint/19686/
http://ir.unimas.my/id/eprint/19686/1/Mohd%20Shahrul.pdf
https://link.springer.com/article/10.1007/s11356-017-0521-1
id ftunivmsarawak:oai:ir.unimas.my:19686
record_format openpolar
institution Open Polar
collection Universiti Malaysia Sarawak: UNIMAS Institutional Repository
op_collection_id ftunivmsarawak
language English
topic GC Oceanography
GE Environmental Sciences
spellingShingle GC Oceanography
GE Environmental Sciences
Mohd Shahrul, Mohd Nadzir
Ashfold, Matthew J.
Md Firoz, Khan
Robinson, Andrew D.
Aazani, Mujahid
Spatial-temporal variations in surface ozone over Ushuaia and the Antarctic region: observations from in situ measurements, satellite data, and global models
topic_facet GC Oceanography
GE Environmental Sciences
description The Antarctic continent is known to be an unpopulated region due to its extreme weather and climate conditions. However, the air quality over this continent can be affected by long-lived anthropogenic pollutants from the mainland. The Argentinian region of Ushuaia is often the main source area of accumulated hazardous gases over the Antarctic Peninsula. The main objective of this study is to report the first in situ observations yet known of surface ozone (O3) over Ushuaia, the Drake Passage, and Coastal Antarctic Peninsula (CAP) on board the RV Australis during the Malaysian Antarctic Scientific Expedition Cruise 2016 (MASEC’16). Hourly O3 data was measured continuously for 23 days using an EcoTech O3 analyzer. To understand more about the distribution of surface O3 over the Antarctic, we present the spatial and temporal of surface O3 of long-term data (2009–2015) obtained online from the World Meteorology Organization of World Data Centre for greenhouse gases (WMO WDCGG). Furthermore, surface O3 satellite data from the free online NOAA-Atmospheric Infrared Sounder (AIRS) database and online data assimilation from the European Centre for Medium-Range Weather Forecasts (ECMWF)-Monitoring Atmospheric Composition and Climate (MACC) were used. The data from both online products are compared to document the data sets and to give an indication of its quality towards in situ data. Finally, we used past carbon monoxide (CO) data as a proxy of surface O3 formation over Ushuaia and the Antarctic region. Our key findings were that the surface O3 mixing ratio during MASEC’16 increased from a minimum of 5 ppb to ~ 10–13 ppb approaching the Drake Passage and the Coastal Antarctic Peninsula (CAP) region. The anthropogenic and biogenic O3 precursors from Ushuaia and the marine region influenced the mixing ratio of surface O3 over the Drake Passage and CAP region. The past data from WDCGG showed that the annual O3 cycle has a maximum during the winter of 30 to 35 ppb between June and August and a minimum during the summer (January to February) of 10 to 20 ppb. The surface O3 mixing ratio during the summer was controlled by photochemical processes in the presence of sunlight, leading to the depletion process. During the winter, the photochemical production of surface O3 was more dominant. The NOAA-AIRS and ECMWF-MACC analysis agreed well with the MASEC’16 data but twice were higher during the expedition period. Finally, the CO past data showed the surface O3 mixing ratio was influenced by the CO mixing ratio over both the Ushuaia and Antarctic regions. Peak surface O3 and CO hourly mixing ratios reached up to ~ 38 ppb (O3) and ~ 500 ppb (CO) over Ushuaia. High CO over Ushuaia led to the depletion process of surface O3 over the region. Monthly CO mixing ratio over Antarctic (South Pole) were low, leading to the production of surface O3 over the Antarctic region. © 2017, Springer-Verlag GmbH Germany.
format Article in Journal/Newspaper
author Mohd Shahrul, Mohd Nadzir
Ashfold, Matthew J.
Md Firoz, Khan
Robinson, Andrew D.
Aazani, Mujahid
author_facet Mohd Shahrul, Mohd Nadzir
Ashfold, Matthew J.
Md Firoz, Khan
Robinson, Andrew D.
Aazani, Mujahid
author_sort Mohd Shahrul, Mohd Nadzir
title Spatial-temporal variations in surface ozone over Ushuaia and the Antarctic region: observations from in situ measurements, satellite data, and global models
title_short Spatial-temporal variations in surface ozone over Ushuaia and the Antarctic region: observations from in situ measurements, satellite data, and global models
title_full Spatial-temporal variations in surface ozone over Ushuaia and the Antarctic region: observations from in situ measurements, satellite data, and global models
title_fullStr Spatial-temporal variations in surface ozone over Ushuaia and the Antarctic region: observations from in situ measurements, satellite data, and global models
title_full_unstemmed Spatial-temporal variations in surface ozone over Ushuaia and the Antarctic region: observations from in situ measurements, satellite data, and global models
title_sort spatial-temporal variations in surface ozone over ushuaia and the antarctic region: observations from in situ measurements, satellite data, and global models
publisher Springer Verlag
publishDate 2018
url http://ir.unimas.my/id/eprint/19686/
http://ir.unimas.my/id/eprint/19686/1/Mohd%20Shahrul.pdf
https://link.springer.com/article/10.1007/s11356-017-0521-1
long_lat ENVELOPE(-40.000,-40.000,-82.167,-82.167)
geographic Antarctic
The Antarctic
Antarctic Peninsula
Drake Passage
South Pole
Ushuaia
geographic_facet Antarctic
The Antarctic
Antarctic Peninsula
Drake Passage
South Pole
Ushuaia
genre Antarc*
Antarctic
Antarctic Peninsula
Drake Passage
South pole
South pole
genre_facet Antarc*
Antarctic
Antarctic Peninsula
Drake Passage
South pole
South pole
op_relation http://ir.unimas.my/id/eprint/19686/1/Mohd%20Shahrul.pdf
Mohd Shahrul, Mohd Nadzir and Ashfold, Matthew J. and Md Firoz, Khan and Robinson, Andrew D. and Aazani, Mujahid (2018) Spatial-temporal variations in surface ozone over Ushuaia and the Antarctic region: observations from in situ measurements, satellite data, and global models. Environmental Science and Pollution Research, 25 (3). pp. 2194-2210. ISSN 0944-1344
_version_ 1766153749478244352
spelling ftunivmsarawak:oai:ir.unimas.my:19686 2023-05-15T13:41:41+02:00 Spatial-temporal variations in surface ozone over Ushuaia and the Antarctic region: observations from in situ measurements, satellite data, and global models Mohd Shahrul, Mohd Nadzir Ashfold, Matthew J. Md Firoz, Khan Robinson, Andrew D. Aazani, Mujahid 2018-01-01 text http://ir.unimas.my/id/eprint/19686/ http://ir.unimas.my/id/eprint/19686/1/Mohd%20Shahrul.pdf https://link.springer.com/article/10.1007/s11356-017-0521-1 en eng Springer Verlag http://ir.unimas.my/id/eprint/19686/1/Mohd%20Shahrul.pdf Mohd Shahrul, Mohd Nadzir and Ashfold, Matthew J. and Md Firoz, Khan and Robinson, Andrew D. and Aazani, Mujahid (2018) Spatial-temporal variations in surface ozone over Ushuaia and the Antarctic region: observations from in situ measurements, satellite data, and global models. Environmental Science and Pollution Research, 25 (3). pp. 2194-2210. ISSN 0944-1344 GC Oceanography GE Environmental Sciences Article PeerReviewed 2018 ftunivmsarawak 2021-04-27T17:12:39Z The Antarctic continent is known to be an unpopulated region due to its extreme weather and climate conditions. However, the air quality over this continent can be affected by long-lived anthropogenic pollutants from the mainland. The Argentinian region of Ushuaia is often the main source area of accumulated hazardous gases over the Antarctic Peninsula. The main objective of this study is to report the first in situ observations yet known of surface ozone (O3) over Ushuaia, the Drake Passage, and Coastal Antarctic Peninsula (CAP) on board the RV Australis during the Malaysian Antarctic Scientific Expedition Cruise 2016 (MASEC’16). Hourly O3 data was measured continuously for 23 days using an EcoTech O3 analyzer. To understand more about the distribution of surface O3 over the Antarctic, we present the spatial and temporal of surface O3 of long-term data (2009–2015) obtained online from the World Meteorology Organization of World Data Centre for greenhouse gases (WMO WDCGG). Furthermore, surface O3 satellite data from the free online NOAA-Atmospheric Infrared Sounder (AIRS) database and online data assimilation from the European Centre for Medium-Range Weather Forecasts (ECMWF)-Monitoring Atmospheric Composition and Climate (MACC) were used. The data from both online products are compared to document the data sets and to give an indication of its quality towards in situ data. Finally, we used past carbon monoxide (CO) data as a proxy of surface O3 formation over Ushuaia and the Antarctic region. Our key findings were that the surface O3 mixing ratio during MASEC’16 increased from a minimum of 5 ppb to ~ 10–13 ppb approaching the Drake Passage and the Coastal Antarctic Peninsula (CAP) region. The anthropogenic and biogenic O3 precursors from Ushuaia and the marine region influenced the mixing ratio of surface O3 over the Drake Passage and CAP region. The past data from WDCGG showed that the annual O3 cycle has a maximum during the winter of 30 to 35 ppb between June and August and a minimum during the summer (January to February) of 10 to 20 ppb. The surface O3 mixing ratio during the summer was controlled by photochemical processes in the presence of sunlight, leading to the depletion process. During the winter, the photochemical production of surface O3 was more dominant. The NOAA-AIRS and ECMWF-MACC analysis agreed well with the MASEC’16 data but twice were higher during the expedition period. Finally, the CO past data showed the surface O3 mixing ratio was influenced by the CO mixing ratio over both the Ushuaia and Antarctic regions. Peak surface O3 and CO hourly mixing ratios reached up to ~ 38 ppb (O3) and ~ 500 ppb (CO) over Ushuaia. High CO over Ushuaia led to the depletion process of surface O3 over the region. Monthly CO mixing ratio over Antarctic (South Pole) were low, leading to the production of surface O3 over the Antarctic region. © 2017, Springer-Verlag GmbH Germany. Article in Journal/Newspaper Antarc* Antarctic Antarctic Peninsula Drake Passage South pole South pole Universiti Malaysia Sarawak: UNIMAS Institutional Repository Antarctic The Antarctic Antarctic Peninsula Drake Passage South Pole Ushuaia ENVELOPE(-40.000,-40.000,-82.167,-82.167)

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