The Development of an Atmospheric Aerosol/Chemistry‐Climate Model, BCC_AGCM_CUACE2.0, and Simulated Effective Radiative Forcing of Nitrate Aerosols

The Development of an Atmospheric Aerosol/Chemistry‐Climate Model, BCC_AGCM_CUACE2.0, and Simulated Effective Radiative Forcing of Nitrate Aerosols

Abstract This study developed a next‐generation atmospheric aerosol/chemistry‐climate model, the BCC_AGCM_CUACE2.0. Then, the performance of the model for nitrate was evaluated, and the nitrate direct radiative forcing (DRF) and effective radiative forcing (ERF) due to aerosol‐radiation interactions...

Full description

Bibliographic Details
Main Authors: Qi An, Hua Zhang, Zhili Wang, Yi Liu, Bing Xie, Qianxia Liu, Zaizhi Wang, Sunling Gong
Format: Article
Language:English
Published: American Geophysical Union (AGU) 2019-11-01
Series:Journal of Advances in Modeling Earth Systems
Online Access:https://doi.org/10.1029/2019MS001622
id doaj-cac963a2d4ef42b787fced391228318b
record_format Article
spelling doaj-cac963a2d4ef42b787fced391228318b2020-11-25T02:32:45ZengAmerican Geophysical Union (AGU)Journal of Advances in Modeling Earth Systems1942-24662019-11-0111113816383510.1029/2019MS001622The Development of an Atmospheric Aerosol/Chemistry‐Climate Model, BCC_AGCM_CUACE2.0, and Simulated Effective Radiative Forcing of Nitrate AerosolsQi An0Hua Zhang1Zhili Wang2Yi Liu3Bing Xie4Qianxia Liu5Zaizhi Wang6Sunling Gong7Key Laboratory of the Middle Atmosphere and Global Environmental Observation (LAGEO), Institute of Atmospheric Physics (IAP) Chinese Academy of Sciences Beijing ChinaState Key Laboratory of Severe Weather and Key Laboratory of Atmospheric Chemistry of China Meteorological Administration Chinese Academy of Meteorological Sciences (CAMS) Beijing ChinaState Key Laboratory of Severe Weather and Key Laboratory of Atmospheric Chemistry of China Meteorological Administration Chinese Academy of Meteorological Sciences (CAMS) Beijing ChinaKey Laboratory of the Middle Atmosphere and Global Environmental Observation (LAGEO), Institute of Atmospheric Physics (IAP) Chinese Academy of Sciences Beijing ChinaNational Climate Center (NCC) Beijing ChinaNational Climate Center (NCC) Beijing ChinaNational Climate Center (NCC) Beijing ChinaState Key Laboratory of Severe Weather and Key Laboratory of Atmospheric Chemistry of China Meteorological Administration Chinese Academy of Meteorological Sciences (CAMS) Beijing ChinaAbstract This study developed a next‐generation atmospheric aerosol/chemistry‐climate model, the BCC_AGCM_CUACE2.0. Then, the performance of the model for nitrate was evaluated, and the nitrate direct radiative forcing (DRF) and effective radiative forcing (ERF) due to aerosol‐radiation interactions were simulated for the present day (2010), near‐term future (2030), and middle‐term future (2050) under the Representative Concentration Pathway 4.5, 6.0, and 8.5 scenarios relative to the preindustrial era (1850). The model reproduced the distributions and seasonal changes in nitrate loading well, and simulated surface concentrations matched observations in Europe, North America, and China. Current global mean annual loading of nitrates was predicted to increase by 1.50 mg m−2 relative to 1850, with the largest increases occurring in East Asia (9.44 mg m−2), Europe (4.36 mg m−2), and South Asia (3.09 mg m−2). The current global mean annual ERF of nitrates was −0.28 W m−2 relative to 1850. Due to global reductions in pollutant emissions, the nitrate ERF values were predicted to decrease to −0.17, −0.20, and −0.24 W m−2 in 2030 and −0.07, −0.18, and −0.19 W m−2 in 2050 for Representative Concentration Pathway 4.5, 6.0, and 8.5 relative to 1850, respectively. Although global mean nitrate values showed a declining trend, future nitrate loading remained high in East Asia and South Asia.https://doi.org/10.1029/2019MS001622
collection DOAJ
language English
format Article
sources DOAJ
author Qi An
Hua Zhang
Zhili Wang
Yi Liu
Bing Xie
Qianxia Liu
Zaizhi Wang
Sunling Gong
spellingShingle Qi An
Hua Zhang
Zhili Wang
Yi Liu
Bing Xie
Qianxia Liu
Zaizhi Wang
Sunling Gong
The Development of an Atmospheric Aerosol/Chemistry‐Climate Model, BCC_AGCM_CUACE2.0, and Simulated Effective Radiative Forcing of Nitrate Aerosols
Journal of Advances in Modeling Earth Systems
author_facet Qi An
Hua Zhang
Zhili Wang
Yi Liu
Bing Xie
Qianxia Liu
Zaizhi Wang
Sunling Gong
author_sort Qi An
title The Development of an Atmospheric Aerosol/Chemistry‐Climate Model, BCC_AGCM_CUACE2.0, and Simulated Effective Radiative Forcing of Nitrate Aerosols
title_short The Development of an Atmospheric Aerosol/Chemistry‐Climate Model, BCC_AGCM_CUACE2.0, and Simulated Effective Radiative Forcing of Nitrate Aerosols
title_full The Development of an Atmospheric Aerosol/Chemistry‐Climate Model, BCC_AGCM_CUACE2.0, and Simulated Effective Radiative Forcing of Nitrate Aerosols
title_fullStr The Development of an Atmospheric Aerosol/Chemistry‐Climate Model, BCC_AGCM_CUACE2.0, and Simulated Effective Radiative Forcing of Nitrate Aerosols
title_full_unstemmed The Development of an Atmospheric Aerosol/Chemistry‐Climate Model, BCC_AGCM_CUACE2.0, and Simulated Effective Radiative Forcing of Nitrate Aerosols
title_sort development of an atmospheric aerosol/chemistry‐climate model, bcc_agcm_cuace2.0, and simulated effective radiative forcing of nitrate aerosols
publisher American Geophysical Union (AGU)
series Journal of Advances in Modeling Earth Systems
issn 1942-2466
publishDate 2019-11-01
description Abstract This study developed a next‐generation atmospheric aerosol/chemistry‐climate model, the BCC_AGCM_CUACE2.0. Then, the performance of the model for nitrate was evaluated, and the nitrate direct radiative forcing (DRF) and effective radiative forcing (ERF) due to aerosol‐radiation interactions were simulated for the present day (2010), near‐term future (2030), and middle‐term future (2050) under the Representative Concentration Pathway 4.5, 6.0, and 8.5 scenarios relative to the preindustrial era (1850). The model reproduced the distributions and seasonal changes in nitrate loading well, and simulated surface concentrations matched observations in Europe, North America, and China. Current global mean annual loading of nitrates was predicted to increase by 1.50 mg m−2 relative to 1850, with the largest increases occurring in East Asia (9.44 mg m−2), Europe (4.36 mg m−2), and South Asia (3.09 mg m−2). The current global mean annual ERF of nitrates was −0.28 W m−2 relative to 1850. Due to global reductions in pollutant emissions, the nitrate ERF values were predicted to decrease to −0.17, −0.20, and −0.24 W m−2 in 2030 and −0.07, −0.18, and −0.19 W m−2 in 2050 for Representative Concentration Pathway 4.5, 6.0, and 8.5 relative to 1850, respectively. Although global mean nitrate values showed a declining trend, future nitrate loading remained high in East Asia and South Asia.
url https://doi.org/10.1029/2019MS001622
work_keys_str_mv AT qian thedevelopmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT huazhang thedevelopmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT zhiliwang thedevelopmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT yiliu thedevelopmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT bingxie thedevelopmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT qianxialiu thedevelopmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT zaizhiwang thedevelopmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT sunlinggong thedevelopmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT qian developmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT huazhang developmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT zhiliwang developmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT yiliu developmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT bingxie developmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT qianxialiu developmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT zaizhiwang developmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
AT sunlinggong developmentofanatmosphericaerosolchemistryclimatemodelbccagcmcuace20andsimulatedeffectiveradiativeforcingofnitrateaerosols
_version_ 1724818051360096256

Similar Items