High-resolution modeling of the distribution of surface air pollutants and their intercontinental transport by a global tropospheric atmospheric chemistry source–receptor model (GNAQPMS-SM)

Many efforts have been devoted to quantifying the impact of intercontinental transport on global air quality by using global chemical transport models with horizontal resolutions of hundreds of kilometers in recent decades. In this study, a global online air quality source–receptor model (GNAQPMS-SM...

Full description

Bibliographic Details
Published in:Geoscientific Model Development
Main Authors: Ye, Qian, Li, Jie, Chen, Xueshun, Chen, Huansheng, Yang, Wenyi, Du, Huiyun, Pan, Xiaole, Tang, Xiao, Wang, Wei, Zhu, Lili, Li, Jianjun, Wang, Zhe, Wang, Zifa
Format: Text
Language:English
Published: 2021
Subjects:
Arctic
Arctic Ocean
Pacific
black carbon
Online Access:https://doi.org/10.5194/gmd-14-7573-2021
https://gmd.copernicus.org/articles/14/7573/2021/
id ftcopernicus:oai:publications.copernicus.org:gmd95411
record_format openpolar
institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description Many efforts have been devoted to quantifying the impact of intercontinental transport on global air quality by using global chemical transport models with horizontal resolutions of hundreds of kilometers in recent decades. In this study, a global online air quality source–receptor model (GNAQPMS-SM) is designed to effectively compute the contributions of various regions to ambient pollutant concentrations. The newly developed model is able to quantify source–receptor (S-R) relationships in one simulation without introducing errors by nonlinear chemistry. We calculate the surface and planetary boundary layer (PBL) S-R relationships in 19 regions over the whole globe for ozone (O 3 ), black carbon (BC), and non-sea-salt sulfate (nss-sulfate) by conducting a high-resolution (0.5 ∘ × 0.5 ∘ ) simulation for the year 2018. The model exhibits a realistic capacity in reproducing the spatial distributions and seasonal variations of tropospheric O 3 , carbon monoxide, and aerosols at global and regional scales – Europe (EUR), North America (NAM), and East Asia (EA). The correlation coefficient ( R ) and normalized mean bias (NMB) for seasonal O 3 at global background and urban–rural sites ranged from 0.49 to 0.87 and − 2 % to 14.97 %, respectively. For aerosols, the R and NMB in EUR, NAM, and EA mostly exceed 0.6 and are within ± 15 %. These statistical parameters based on this global simulation can match those of regional models in key regions. The simulated tropospheric nitrogen dioxide and aerosol optical depths are generally in agreement with satellite observations. The model overestimates ozone concentrations in the upper troposphere and stratosphere in the tropics, midlatitude, and polar regions of the Southern Hemisphere due to the use of a simplified stratospheric ozone scheme and/or biases in estimated stratosphere–troposphere exchange dynamics. We find that surface O 3 can travel a long distance and contributes a non-negligible fraction to downwind regions. Non-local source transport explains approximately 35 %–60 % of surface O 3 in EA, South Asia (SAS), EUR, and NAM. The O 3 exported from EUR can also be transported across the Arctic Ocean to the North Pacific and contributes nearly 5 %–7.5 % to the North Pacific. BC is directly linked to local emissions, and each BC source region mainly contributes to itself and surrounding regions. For nss-sulfate, contributions of long-range transport account for 15 %–30 % within the PBL in EA, SAS, EUR, and NAM. Our estimated international transport of BC and nss-sulfate is lower than that from the Hemispheric Transport of Air Pollution (HTAP) assessment report in 2010, but most surface O 3 results are within the range. This difference may be related to the different simulation years, emission inventories, vertical and horizontal resolutions, and S-R revealing methods. Additional emission sensitivity simulation shows a negative O 3 response in receptor region EA in January from EA. The difference between two methods in estimated S-R relationships of nss-sulfate and O 3 are mainly due to ignoring the nonlinearity of pollutants during chemical processes. The S-R relationship of aerosols within EA subcontinent is also assessed. The model that we developed creates a link between the scientific community and policymakers. Finally, the results are discussed in the context of future model development and analysis opportunities.
format Text
author Ye, Qian
Li, Jie
Chen, Xueshun
Chen, Huansheng
Yang, Wenyi
Du, Huiyun
Pan, Xiaole
Tang, Xiao
Wang, Wei
Zhu, Lili
Li, Jianjun
Wang, Zhe
Wang, Zifa
spellingShingle Ye, Qian
Li, Jie
Chen, Xueshun
Chen, Huansheng
Yang, Wenyi
Du, Huiyun
Pan, Xiaole
Tang, Xiao
Wang, Wei
Zhu, Lili
Li, Jianjun
Wang, Zhe
Wang, Zifa
High-resolution modeling of the distribution of surface air pollutants and their intercontinental transport by a global tropospheric atmospheric chemistry source–receptor model (GNAQPMS-SM)
author_facet Ye, Qian
Li, Jie
Chen, Xueshun
Chen, Huansheng
Yang, Wenyi
Du, Huiyun
Pan, Xiaole
Tang, Xiao
Wang, Wei
Zhu, Lili
Li, Jianjun
Wang, Zhe
Wang, Zifa
author_sort Ye, Qian
title High-resolution modeling of the distribution of surface air pollutants and their intercontinental transport by a global tropospheric atmospheric chemistry source–receptor model (GNAQPMS-SM)
title_short High-resolution modeling of the distribution of surface air pollutants and their intercontinental transport by a global tropospheric atmospheric chemistry source–receptor model (GNAQPMS-SM)
title_full High-resolution modeling of the distribution of surface air pollutants and their intercontinental transport by a global tropospheric atmospheric chemistry source–receptor model (GNAQPMS-SM)
title_fullStr High-resolution modeling of the distribution of surface air pollutants and their intercontinental transport by a global tropospheric atmospheric chemistry source–receptor model (GNAQPMS-SM)
title_full_unstemmed High-resolution modeling of the distribution of surface air pollutants and their intercontinental transport by a global tropospheric atmospheric chemistry source–receptor model (GNAQPMS-SM)
title_sort high-resolution modeling of the distribution of surface air pollutants and their intercontinental transport by a global tropospheric atmospheric chemistry source–receptor model (gnaqpms-sm)
publishDate 2021
url https://doi.org/10.5194/gmd-14-7573-2021
https://gmd.copernicus.org/articles/14/7573/2021/
geographic Arctic
Arctic Ocean
Pacific
geographic_facet Arctic
Arctic Ocean
Pacific
genre Arctic
Arctic Ocean
black carbon
genre_facet Arctic
Arctic Ocean
black carbon
op_source eISSN: 1991-9603
op_relation doi:10.5194/gmd-14-7573-2021
https://gmd.copernicus.org/articles/14/7573/2021/
op_doi https://doi.org/10.5194/gmd-14-7573-2021
container_title Geoscientific Model Development
container_volume 14
container_issue 12
container_start_page 7573
op_container_end_page 7604
_version_ 1766350234311458816
spelling ftcopernicus:oai:publications.copernicus.org:gmd95411 2023-05-15T15:20:01+02:00 High-resolution modeling of the distribution of surface air pollutants and their intercontinental transport by a global tropospheric atmospheric chemistry source–receptor model (GNAQPMS-SM) Ye, Qian Li, Jie Chen, Xueshun Chen, Huansheng Yang, Wenyi Du, Huiyun Pan, Xiaole Tang, Xiao Wang, Wei Zhu, Lili Li, Jianjun Wang, Zhe Wang, Zifa 2021-12-16 application/pdf https://doi.org/10.5194/gmd-14-7573-2021 https://gmd.copernicus.org/articles/14/7573/2021/ eng eng doi:10.5194/gmd-14-7573-2021 https://gmd.copernicus.org/articles/14/7573/2021/ eISSN: 1991-9603 Text 2021 ftcopernicus https://doi.org/10.5194/gmd-14-7573-2021 2021-12-20T17:22:31Z Many efforts have been devoted to quantifying the impact of intercontinental transport on global air quality by using global chemical transport models with horizontal resolutions of hundreds of kilometers in recent decades. In this study, a global online air quality source–receptor model (GNAQPMS-SM) is designed to effectively compute the contributions of various regions to ambient pollutant concentrations. The newly developed model is able to quantify source–receptor (S-R) relationships in one simulation without introducing errors by nonlinear chemistry. We calculate the surface and planetary boundary layer (PBL) S-R relationships in 19 regions over the whole globe for ozone (O 3 ), black carbon (BC), and non-sea-salt sulfate (nss-sulfate) by conducting a high-resolution (0.5 ∘ × 0.5 ∘ ) simulation for the year 2018. The model exhibits a realistic capacity in reproducing the spatial distributions and seasonal variations of tropospheric O 3 , carbon monoxide, and aerosols at global and regional scales – Europe (EUR), North America (NAM), and East Asia (EA). The correlation coefficient ( R ) and normalized mean bias (NMB) for seasonal O 3 at global background and urban–rural sites ranged from 0.49 to 0.87 and − 2 % to 14.97 %, respectively. For aerosols, the R and NMB in EUR, NAM, and EA mostly exceed 0.6 and are within ± 15 %. These statistical parameters based on this global simulation can match those of regional models in key regions. The simulated tropospheric nitrogen dioxide and aerosol optical depths are generally in agreement with satellite observations. The model overestimates ozone concentrations in the upper troposphere and stratosphere in the tropics, midlatitude, and polar regions of the Southern Hemisphere due to the use of a simplified stratospheric ozone scheme and/or biases in estimated stratosphere–troposphere exchange dynamics. We find that surface O 3 can travel a long distance and contributes a non-negligible fraction to downwind regions. Non-local source transport explains approximately 35 %–60 % of surface O 3 in EA, South Asia (SAS), EUR, and NAM. The O 3 exported from EUR can also be transported across the Arctic Ocean to the North Pacific and contributes nearly 5 %–7.5 % to the North Pacific. BC is directly linked to local emissions, and each BC source region mainly contributes to itself and surrounding regions. For nss-sulfate, contributions of long-range transport account for 15 %–30 % within the PBL in EA, SAS, EUR, and NAM. Our estimated international transport of BC and nss-sulfate is lower than that from the Hemispheric Transport of Air Pollution (HTAP) assessment report in 2010, but most surface O 3 results are within the range. This difference may be related to the different simulation years, emission inventories, vertical and horizontal resolutions, and S-R revealing methods. Additional emission sensitivity simulation shows a negative O 3 response in receptor region EA in January from EA. The difference between two methods in estimated S-R relationships of nss-sulfate and O 3 are mainly due to ignoring the nonlinearity of pollutants during chemical processes. The S-R relationship of aerosols within EA subcontinent is also assessed. The model that we developed creates a link between the scientific community and policymakers. Finally, the results are discussed in the context of future model development and analysis opportunities. Text Arctic Arctic Ocean black carbon Copernicus Publications: E-Journals Arctic Arctic Ocean Pacific Geoscientific Model Development 14 12 7573 7604

Similar Items