[[File:Tianci Jiang.jpeg|200px|thumb|left]]

'''姜天赐'''
'''Tianci Jiang'''

Master's student,

School of Environment,

Southern University of Science of Technology

Email: jiangtc2019@mail.sustech.edu.cn

=Education 教育背景=

* 2023 至今南方科技大学环境科学与工程地球物理学硕士在读 M.S. candidate in Geophysics, School of Environment, Southern University of Science and Technology
* 2019-2023 南方科技大学环境科学与工程水文与水资源工程学士 B.S. in Hydrology and Water Resources Engineering, School of Environment, Southern University of Science and Technology

=Research interest 研究兴趣=
Atmospheric Oxidation Capacity 大气氧化性研究

Tianci JIANG

2023-11-01T07:47:52Z

Atomoschem:

Papers:Wang et al 2022

2023-10-30T03:04:03Z

Atomoschem:

[[Image:Wang_et_al_2022.jpg|center|500px|Wang et al 2022]]

'''Abstract |''' We combined observations and simulations to assess tropospheric ozone trends over Southeast Asia from 2005 to 2016. Multi-platform observations showed that surface ozone had been increasing at rates of 0.7–1.2 ppb year^−1 over the Peninsular Southeast Asia (PSEA) and 0.2–0.4 ppb year^−1 over the Maritime Continents (MC); tropospheric ozone columns had been rising throughout Southeast Asia by 0.21–0.35 DU year^−1. These observed ozone trends were better reproduced by simulations driven with satellite-constrained NOx emissions, indicating that NOx emission growths may have been underestimated for the PSEA and overestimated for the MC in the Community Emissions Data System and the Global Fire Emissions Data set. The surface ozone increases over the PSEA were driven by rapidly growing local emissions, wherein fire emission growths may still be underestimated even with satellite constraints. We highlighted the need for better quantifying Southeast Asian emissions to benefit air quality management.

'''Publication |''' '''Wang, X.''', '''Fu, T.-M.*''', Zhang, L.*, Lu, X., Liu, X., Amnuaylojaroen, T., Latif, M. T., '''Ma, Y.''', '''Zhang, L.''', '''Feng, X.''', Zhu, L., Shen, H., Yang, X. (2022), Rapidly changing emissions drove substantial surface and tropospheric ozone increases over Southeast Asia, ''Geophysical Research Letters'', e2022GL100223, doi:10.1029/2022GL100223. [https://atmoschem.org.cn/papers/Wang_et_al_2022_Geophysical_Research_Letters.pdf PDF] [https://agupubs.onlinelibrary.wiley.com/doi/epdf/10.1029/2022GL100223 Full text].

Papers:Wang et al 2022

2023-10-30T03:03:16Z

Atomoschem: Created page with "Wang et al 2022 '''Abstract |''' We combined observations and simulations to assess tropospheric ozone trends over Southeast Asia f..."

[[Image:Wang et al 2022.jpg|center|500px|Wang et al 2022]]

'''Abstract |''' We combined observations and simulations to assess tropospheric ozone trends over Southeast Asia from 2005 to 2016. Multi-platform observations showed that surface ozone had been increasing at rates of 0.7–1.2 ppb year^−1 over the Peninsular Southeast Asia (PSEA) and 0.2–0.4 ppb year^−1 over the Maritime Continents (MC); tropospheric ozone columns had been rising throughout Southeast Asia by 0.21–0.35 DU year^−1. These observed ozone trends were better reproduced by simulations driven with satellite-constrained NOx emissions, indicating that NOx emission growths may have been underestimated for the PSEA and overestimated for the MC in the Community Emissions Data System and the Global Fire Emissions Data set. The surface ozone increases over the PSEA were driven by rapidly growing local emissions, wherein fire emission growths may still be underestimated even with satellite constraints. We highlighted the need for better quantifying Southeast Asian emissions to benefit air quality management.

'''Publication |''' '''Wang, X.''', '''Fu, T.-M.*''', Zhang, L.*, Lu, X., Liu, X., Amnuaylojaroen, T., Latif, M. T., '''Ma, Y.''', '''Zhang, L.''', '''Feng, X.''', Zhu, L., Shen, H., Yang, X. (2022), Rapidly changing emissions drove substantial surface and tropospheric ozone increases over Southeast Asia, ''Geophysical Research Letters'', e2022GL100223, doi:10.1029/2022GL100223. [https://atmoschem.org.cn/papers/Wang_et_al_2022_Geophysical_Research_Letters.pdf PDF] [https://agupubs.onlinelibrary.wiley.com/doi/epdf/10.1029/2022GL100223 Full text].

File:Wang et al 2022 pic.jpg

2023-10-30T02:58:13Z

Atomoschem: Atomoschem moved page File:Wang et al 2023 pic.jpg to File:Wang et al 2022 pic.jpg

File:Wang et al 2023 pic.jpg

2023-10-30T02:58:13Z

Atomoschem: Atomoschem moved page File:Wang et al 2023 pic.jpg to File:Wang et al 2022 pic.jpg

#REDIRECT [[File:Wang et al 2022 pic.jpg]]

File:Wang et al 2022 pic.jpg

2023-10-30T02:57:33Z

Atomoschem:

Research

2023-10-30T02:50:41Z

Atomoschem: /* Sources of air pollutants */

=Chemistry-Meteorology Interactions and Chemistry-Meteorology Model Development=
Team members: [[Yiheng CHEN]], [[Yumin LI]], [[Wei TAO]], [[Wenlu WU]], [[Aoxing ZHANG]], [[Tzung-May FU]]

{{Box|type=l_red_light|text='''WRF-GC (v2.0): online two-way coupling of WRF (v3.9.1.1) and GEOS-Chem (v12.7.2) for modeling regional atmospheric chemistry-meteorology interactions'''

{{HideProject|
{{:Papers:Feng_et_al_2021}}
}}
}}

{{Box|type=l_red_light|text='''WRF-GC (v1.0): online coupling of WRF (v3.9.1.1) and GEOS-Chem (v12.2.1) for regional atmospheric chemistry modeling – Part 1: Description of the one-way model'''

{{HideProject|
{{:Papers:Lin_et_al_2020}}
}}
}}

{{Box|type=l_red_light|text='''Anthropogenic aerosols significantly reduce mesoscale convective system occurrences and precipitation over Southern China in April
'''

{{HideProject|
{{:Papers:Zhang_et_al_2020}}
}}
}}

{{Box|type=l_red_light|text='''Positive but variable sensitivity of August surface ozone to large-scale warming in the southeast United States'''

{{HideProject|
{{:Papers:Fu_et_al_2015}}
}}
}}

{{Box|type=l_red_light|text='''Contributions of Organic Aerosols to Cloud Condensation Nuclei Numbers in China'''

{{HideProject|
{{:Papers:Xing_and_Fu_2014}}
}}
}}

=Tropospheric and surface ozone=
Team members: [[Jiongkai CHEN]], [[Xiaolin WANG]], [[Aoxing ZHANG]], [[Wenlu WU]], [[Enyu XIONG]], [[Jiajia MO]], [[Tzung-May FU]]

{{Box|type=l_red_light|text='''Deep learning-based ensemble forecasts and predictability assessments for surface ozone pollution'''

{{HideProject|
{{:Papers:Zhang_et_al_2023}}
}}
}}

{{Box|type=l_red_light|text='''Sensitivities of ozone air pollution in the Beijing-Tianjin-Hebei area to local and upwind precursor emissions using adjoint modelling'''

{{HideProject|
{{:Papers:Wang_et_al_2021}}
}}
}}

{{Box|type=l_red_light|text='''Positive but variable sensitivity of August surface ozone to large-scale warming in the southeast United States'''

{{HideProject|
{{:Papers:Fu_et_al_2015}}
}}
}}

=Sources of air pollutants=
Team members: [[Aoxing ZHANG]], [[Xu FENG]], [[Yumin LI]], [[Tzung-May FU]]

{{Box|type=l_red_light|text='''Impacts of ship emissions on air quality in Southern China: opportunistic insights from the abrupt emission changes in early 2020'''

{{HideProject|
{{:Papers:Feng_et_al_2023}}
}}
}}

{{Box|type=l_red_light|text='''Efficient atmospheric transport of microplastics over Asia and adjacent oceans'''

{{HideProject|
{{:Papers:Long_et_al_2022}}
}}
}}

{{Box|type=l_red_light|text='''Impacts of chemical degradation on the global budget of atmospheric levoglucosan and its use as a biomass burning tracer'''

{{HideProject|
{{:Papers:Li_et_al_2021}}
}}
}}

{{Box|type=l_red_light|text='''Adjoint inversion of Chinese non-methane volatile organic compound emissions using space-based observations of formaldehyde and glyoxal'''

{{HideProject|
{{:Papers:Cao_et_al_2018}}
}}
}}

{{Box|type=l_red_light|text='''Carbonaceous aerosols in China: top-down constraints on primary sources and estimation of secondary contribution'''

{{HideProject|
{{:Papers:Fu_et_al_2012}}
}}
}}

=Volatile organic compounds (VOCs): global and regional emissions and impacts=
Team members: [[Wenlu WU]], [[Xiaolin WANG]], [[Aoxing ZHANG]]

Volatile organic compounds (VOC) impact the oxidizing power of the atmosphere and produce ozone and secondary organic aerosols. VOCs are emitted into the atmosphere from both natural and anthropogenic activities, and quantifying these many overlapping sources can be a challenge. We use remote sensing (satellite) and in situ observations to make 'top-down' estimates of VOC emissions from different sources. We use chemical transport models to evaluate the impact of VOCs on tropospheric chemistry.

{{Box|type=l_red_light|text='''Adjoint inversion of Chinese non-methane volatile organic compound emissions using space-based observations of formaldehyde and glyoxal'''

{{HideProject|
{{:Papers:Cao_et_al_2018}}
}}
}}

{{Box|type=l_red_light|text='''Global budgets of atmospheric glyoxal and methylglyoxal, and implications for formation of secondary organic aerosols'''

{{HideProject|
{{:Papers:Fu_et_al_2008}}
}}
}}

{{Box|type=l_red_light|text='''Space-based formaldehyde measurements as constraints on volatile organic compound emissions in east and south Asia and implications for ozone'''

{{HideProject|
{{:Papers:Fu_et_al_2007}}
}}
}}

{{Box|type=l_red_light|text='''Using satellite HCHO observations to constrain biogenic isoprene emissions in North America'''

{{HideProject|
Publications : Millet et al. [2007], Palmer et al. [2006]
}}
}}

=Organic aerosols (OA)=
Team members: [[Yumin LI]], [[Tzung-May FU]]

{{Box|type=l_red_light|text='''Impacts of chemical degradation on the global budget of atmospheric levoglucosan and its use as a biomass burning tracer'''

{{HideProject|
{{:Papers:Li_et_al_2021}}
}}
}}

{{Box|type=l_red_light|text='''Parameterized yields of semi-volatile products from isoprene oxidation under different NOx levels:impacts of chemical aging and wall-loss of reactive gases'''

{{HideProject|
{{:Papers:Xing_et_al_2018}}
}}
}}

{{Box|type=l_red_light|text='''Global budgets of atmospheric glyoxal and methylglyoxal, and implications for formation of secondary organic aerosols'''

{{HideProject|
{{:Papers:Fu_et_al_2008}}
}}
}}

{{Box|type=l_red_light|text='''Carbonaceous aerosols in China: top-down constraints on primary sources and estimation of secondary contribution'''

{{HideProject|
{{:Papers:Fu_et_al_2012}}
}}
}}

{{Box|type=l_red_light|text='''Sources of secondary organic aerosols in the Pearl River Delta region in fall: Contributions from the aqueous reactive uptake of dicarbonyls'''

{{HideProject|
{{:Papers:Li_et_al_2013}}
}}
}}

{{Box|type=l_red_light|text='''Seasonal and spatial variability of the OM/OC mass ratios and high regional correlation between oxalic acid and zinc in Chinese urban organic aerosols'''

{{HideProject|
{{:Papers:Xing_et_al_2013}}
}}
}}

{{Box|type=l_red_light|text='''A new physically-based parameterization scheme for organic aerosol size evolution'''

{{HideProject|
Xing et al., in progress.
}}
}}

=Air-sea exchange of organic materials=
Team members: [[Cenlin HE]], [[Tzung-May FU]]

The ocean can act both as a source and a sink of atmospheric organic material. The air/sea exchange of organic materials is complexly regulated by both physical and biological conditions at the interface and poorly understood. We developed a new conceptual model to account for these physical and biological processes, including the presence of microfilms, production/consumption of organic matter by marine life, and other photochemical processes.

{{Box|type=l_red_light|text='''Air-Sea Exchange of Volatile Organic Compounds: A New Model with Microlayer Effects'''

{{HideProject|
{{:Papers:He_and_Fu_2012}}
}}
}}

Papers:Feng et al 2023

2023-10-30T02:49:50Z

Atomoschem: Created page with "Feng et al 2023 '''Abstract |''' In early 2020, two unique events perturbed ship emissions of pollutants around Souther..."

[[Image:Feng et al 2023 ship COVID.jpeg|center|500px|Feng et al 2023]]

'''Abstract |''' In early 2020, two unique events perturbed ship emissions of pollutants around Southern China, proffering insights into the impacts of ship emissions on regional air quality: the decline of ship activities due to COVID-19 and the global enforcement of low-sulfur (<0.5%) fuel oil for ships. In January and February 2020, estimated ship emissions of NOx, SO2, and primary PM2.5 over Southern China dropped by 19, 71, and 58%, respectively, relative to the same period in 2019. The decline of ship NOx emissions was mostly over the coastal waters and inland waterways of Southern China due to reduced ship activities. The decline of ship SO2 and primary PM2.5 emissions was most pronounced outside the Chinese Domestic Emission Control Area due to the switch to low-sulfur fuel oil there. Ship emission reductions in early 2020 drove 16 to 18% decreases in surface NO2 levels but 3.8 to 4.9% increases in surface ozone over Southern China. We estimated that ship emissions contributed 40% of surface NO2 concentrations over Guangdong in winter. Our results indicated that future abatements of ship emissions should be implemented synergistically with reductions of land-borne anthropogenic emissions of nonmethane volatile organic compounds to effectively alleviate regional ozone pollution.

'''Publication |''' '''Feng, X.''', '''Ma, Y.''', '''Lin, H.''', '''Fu, T.-M.*''', Zhang, Y., '''Wang, X.''', '''Zhang, A.''', Yuan, Y., Han, Z., Mao, J., Wang, D., Zhu, L., '''Wu, Y.''', Li, Y., Yang, X. (2023), Impacts of ship emissions on air quality in Southern China: opportunistic insights from the abrupt emission changes in early 2020, ''Environmental Science & Technology'', doi:10.1021/acs.est.3c04155. [https://atmoschem.org.cn/papers/1Feng_et_al_2023-Impacts-of-ship-emissions-on-air-quality-in-southern-china-opportunistic-insights-from-the-abrupt.pdf PDF] [https://pubs.acs.org/doi/epdf/10.1021/acs.est.3c04155 Full text]

Research

2023-10-30T02:32:41Z

Atomoschem: /* Sources of air pollutants */

=Chemistry-Meteorology Interactions and Chemistry-Meteorology Model Development=
Team members: [[Yiheng CHEN]], [[Yumin LI]], [[Wei TAO]], [[Wenlu WU]], [[Aoxing ZHANG]], [[Tzung-May FU]]

{{Box|type=l_red_light|text='''WRF-GC (v2.0): online two-way coupling of WRF (v3.9.1.1) and GEOS-Chem (v12.7.2) for modeling regional atmospheric chemistry-meteorology interactions'''

{{HideProject|
{{:Papers:Feng_et_al_2021}}
}}
}}

{{Box|type=l_red_light|text='''WRF-GC (v1.0): online coupling of WRF (v3.9.1.1) and GEOS-Chem (v12.2.1) for regional atmospheric chemistry modeling – Part 1: Description of the one-way model'''

{{HideProject|
{{:Papers:Lin_et_al_2020}}
}}
}}

{{Box|type=l_red_light|text='''Anthropogenic aerosols significantly reduce mesoscale convective system occurrences and precipitation over Southern China in April
'''

{{HideProject|
{{:Papers:Zhang_et_al_2020}}
}}
}}

{{Box|type=l_red_light|text='''Positive but variable sensitivity of August surface ozone to large-scale warming in the southeast United States'''

{{HideProject|
{{:Papers:Fu_et_al_2015}}
}}
}}

{{Box|type=l_red_light|text='''Contributions of Organic Aerosols to Cloud Condensation Nuclei Numbers in China'''

{{HideProject|
{{:Papers:Xing_and_Fu_2014}}
}}
}}

=Tropospheric and surface ozone=
Team members: [[Jiongkai CHEN]], [[Xiaolin WANG]], [[Aoxing ZHANG]], [[Wenlu WU]], [[Enyu XIONG]], [[Jiajia MO]], [[Tzung-May FU]]

{{Box|type=l_red_light|text='''Deep learning-based ensemble forecasts and predictability assessments for surface ozone pollution'''

{{HideProject|
{{:Papers:Zhang_et_al_2023}}
}}
}}

{{Box|type=l_red_light|text='''Sensitivities of ozone air pollution in the Beijing-Tianjin-Hebei area to local and upwind precursor emissions using adjoint modelling'''

{{HideProject|
{{:Papers:Wang_et_al_2021}}
}}
}}

{{Box|type=l_red_light|text='''Positive but variable sensitivity of August surface ozone to large-scale warming in the southeast United States'''

{{HideProject|
{{:Papers:Fu_et_al_2015}}
}}
}}

=Sources of air pollutants=
Team members: [[Aoxing ZHANG]], [[Xu Feng]], [[Yumin LI]], [[Tzung-May FU]]

{{Box|type=l_red_light|text='''Impacts of ship emissions on air quality in Southern China: opportunistic insights from the abrupt emission changes in early 2020'''

{{HideProject|
{{:Papers:Feng_et_al_2023}}
}}
}}

{{Box|type=l_red_light|text='''Efficient atmospheric transport of microplastics over Asia and adjacent oceans'''

{{HideProject|
{{:Papers:Long_et_al_2022}}
}}
}}

{{Box|type=l_red_light|text='''Impacts of chemical degradation on the global budget of atmospheric levoglucosan and its use as a biomass burning tracer'''

{{HideProject|
{{:Papers:Li_et_al_2021}}
}}
}}

{{Box|type=l_red_light|text='''Adjoint inversion of Chinese non-methane volatile organic compound emissions using space-based observations of formaldehyde and glyoxal'''

{{HideProject|
{{:Papers:Cao_et_al_2018}}
}}
}}

{{Box|type=l_red_light|text='''Carbonaceous aerosols in China: top-down constraints on primary sources and estimation of secondary contribution'''

{{HideProject|
{{:Papers:Fu_et_al_2012}}
}}
}}

=Volatile organic compounds (VOCs): global and regional emissions and impacts=
Team members: [[Wenlu WU]], [[Xiaolin WANG]], [[Aoxing ZHANG]]

Volatile organic compounds (VOC) impact the oxidizing power of the atmosphere and produce ozone and secondary organic aerosols. VOCs are emitted into the atmosphere from both natural and anthropogenic activities, and quantifying these many overlapping sources can be a challenge. We use remote sensing (satellite) and in situ observations to make 'top-down' estimates of VOC emissions from different sources. We use chemical transport models to evaluate the impact of VOCs on tropospheric chemistry.

{{Box|type=l_red_light|text='''Adjoint inversion of Chinese non-methane volatile organic compound emissions using space-based observations of formaldehyde and glyoxal'''

{{HideProject|
{{:Papers:Cao_et_al_2018}}
}}
}}

{{Box|type=l_red_light|text='''Global budgets of atmospheric glyoxal and methylglyoxal, and implications for formation of secondary organic aerosols'''

{{HideProject|
{{:Papers:Fu_et_al_2008}}
}}
}}

{{Box|type=l_red_light|text='''Space-based formaldehyde measurements as constraints on volatile organic compound emissions in east and south Asia and implications for ozone'''

{{HideProject|
{{:Papers:Fu_et_al_2007}}
}}
}}

{{Box|type=l_red_light|text='''Using satellite HCHO observations to constrain biogenic isoprene emissions in North America'''

{{HideProject|
Publications : Millet et al. [2007], Palmer et al. [2006]
}}
}}

=Organic aerosols (OA)=
Team members: [[Yumin LI]], [[Tzung-May FU]]

{{Box|type=l_red_light|text='''Impacts of chemical degradation on the global budget of atmospheric levoglucosan and its use as a biomass burning tracer'''

{{HideProject|
{{:Papers:Li_et_al_2021}}
}}
}}

{{Box|type=l_red_light|text='''Parameterized yields of semi-volatile products from isoprene oxidation under different NOx levels:impacts of chemical aging and wall-loss of reactive gases'''

{{HideProject|
{{:Papers:Xing_et_al_2018}}
}}
}}

{{Box|type=l_red_light|text='''Global budgets of atmospheric glyoxal and methylglyoxal, and implications for formation of secondary organic aerosols'''

{{HideProject|
{{:Papers:Fu_et_al_2008}}
}}
}}

{{Box|type=l_red_light|text='''Carbonaceous aerosols in China: top-down constraints on primary sources and estimation of secondary contribution'''

{{HideProject|
{{:Papers:Fu_et_al_2012}}
}}
}}

{{Box|type=l_red_light|text='''Sources of secondary organic aerosols in the Pearl River Delta region in fall: Contributions from the aqueous reactive uptake of dicarbonyls'''

{{HideProject|
{{:Papers:Li_et_al_2013}}
}}
}}

{{Box|type=l_red_light|text='''Seasonal and spatial variability of the OM/OC mass ratios and high regional correlation between oxalic acid and zinc in Chinese urban organic aerosols'''

{{HideProject|
{{:Papers:Xing_et_al_2013}}
}}
}}

{{Box|type=l_red_light|text='''A new physically-based parameterization scheme for organic aerosol size evolution'''

{{HideProject|
Xing et al., in progress.
}}
}}

=Air-sea exchange of organic materials=
Team members: [[Cenlin HE]], [[Tzung-May FU]]

The ocean can act both as a source and a sink of atmospheric organic material. The air/sea exchange of organic materials is complexly regulated by both physical and biological conditions at the interface and poorly understood. We developed a new conceptual model to account for these physical and biological processes, including the presence of microfilms, production/consumption of organic matter by marine life, and other photochemical processes.

{{Box|type=l_red_light|text='''Air-Sea Exchange of Volatile Organic Compounds: A New Model with Microlayer Effects'''

{{HideProject|
{{:Papers:He_and_Fu_2012}}
}}
}}

Research

2023-10-30T02:30:40Z

Atomoschem: /* Sources of air pollutants */

=Chemistry-Meteorology Interactions and Chemistry-Meteorology Model Development=
Team members: [[Yiheng CHEN]], [[Yumin LI]], [[Wei TAO]], [[Wenlu WU]], [[Aoxing ZHANG]], [[Tzung-May FU]]

{{Box|type=l_red_light|text='''WRF-GC (v2.0): online two-way coupling of WRF (v3.9.1.1) and GEOS-Chem (v12.7.2) for modeling regional atmospheric chemistry-meteorology interactions'''

{{HideProject|
{{:Papers:Feng_et_al_2021}}
}}
}}

{{Box|type=l_red_light|text='''WRF-GC (v1.0): online coupling of WRF (v3.9.1.1) and GEOS-Chem (v12.2.1) for regional atmospheric chemistry modeling – Part 1: Description of the one-way model'''

{{HideProject|
{{:Papers:Lin_et_al_2020}}
}}
}}

{{Box|type=l_red_light|text='''Anthropogenic aerosols significantly reduce mesoscale convective system occurrences and precipitation over Southern China in April
'''

{{HideProject|
{{:Papers:Zhang_et_al_2020}}
}}
}}

{{Box|type=l_red_light|text='''Positive but variable sensitivity of August surface ozone to large-scale warming in the southeast United States'''

{{HideProject|
{{:Papers:Fu_et_al_2015}}
}}
}}

{{Box|type=l_red_light|text='''Contributions of Organic Aerosols to Cloud Condensation Nuclei Numbers in China'''

{{HideProject|
{{:Papers:Xing_and_Fu_2014}}
}}
}}

=Tropospheric and surface ozone=
Team members: [[Jiongkai CHEN]], [[Xiaolin WANG]], [[Aoxing ZHANG]], [[Wenlu WU]], [[Enyu XIONG]], [[Jiajia MO]], [[Tzung-May FU]]

{{Box|type=l_red_light|text='''Deep learning-based ensemble forecasts and predictability assessments for surface ozone pollution'''

{{HideProject|
{{:Papers:Zhang_et_al_2023}}
}}
}}

{{Box|type=l_red_light|text='''Sensitivities of ozone air pollution in the Beijing-Tianjin-Hebei area to local and upwind precursor emissions using adjoint modelling'''

{{HideProject|
{{:Papers:Wang_et_al_2021}}
}}
}}

{{Box|type=l_red_light|text='''Positive but variable sensitivity of August surface ozone to large-scale warming in the southeast United States'''

{{HideProject|
{{:Papers:Fu_et_al_2015}}
}}
}}

=Sources of air pollutants=
Team members: [[Aoxing ZHANG]], [[Xu Feng]], [[Yumin LI]], [[Tzung-May FU]]

{{Box|type=l_red_light|text='''Impacts of ship emissions on air quality in Southern China: opportunistic insights from the abrupt emission changes in early 2020'''

{{HideProject|
{{:Papers:Feng et al 2023}}
}}
}}

{{Box|type=l_red_light|text='''Efficient atmospheric transport of microplastics over Asia and adjacent oceans'''

{{HideProject|
{{:Papers:Long_et_al_2022}}
}}
}}

{{Box|type=l_red_light|text='''Impacts of chemical degradation on the global budget of atmospheric levoglucosan and its use as a biomass burning tracer'''

{{HideProject|
{{:Papers:Li_et_al_2021}}
}}
}}

{{Box|type=l_red_light|text='''Adjoint inversion of Chinese non-methane volatile organic compound emissions using space-based observations of formaldehyde and glyoxal'''

{{HideProject|
{{:Papers:Cao_et_al_2018}}
}}
}}

{{Box|type=l_red_light|text='''Carbonaceous aerosols in China: top-down constraints on primary sources and estimation of secondary contribution'''

{{HideProject|
{{:Papers:Fu_et_al_2012}}
}}
}}

=Volatile organic compounds (VOCs): global and regional emissions and impacts=
Team members: [[Wenlu WU]], [[Xiaolin WANG]], [[Aoxing ZHANG]]

Volatile organic compounds (VOC) impact the oxidizing power of the atmosphere and produce ozone and secondary organic aerosols. VOCs are emitted into the atmosphere from both natural and anthropogenic activities, and quantifying these many overlapping sources can be a challenge. We use remote sensing (satellite) and in situ observations to make 'top-down' estimates of VOC emissions from different sources. We use chemical transport models to evaluate the impact of VOCs on tropospheric chemistry.

{{Box|type=l_red_light|text='''Adjoint inversion of Chinese non-methane volatile organic compound emissions using space-based observations of formaldehyde and glyoxal'''

{{HideProject|
{{:Papers:Cao_et_al_2018}}
}}
}}

{{Box|type=l_red_light|text='''Global budgets of atmospheric glyoxal and methylglyoxal, and implications for formation of secondary organic aerosols'''

{{HideProject|
{{:Papers:Fu_et_al_2008}}
}}
}}

{{Box|type=l_red_light|text='''Space-based formaldehyde measurements as constraints on volatile organic compound emissions in east and south Asia and implications for ozone'''

{{HideProject|
{{:Papers:Fu_et_al_2007}}
}}
}}

{{Box|type=l_red_light|text='''Using satellite HCHO observations to constrain biogenic isoprene emissions in North America'''

{{HideProject|
Publications : Millet et al. [2007], Palmer et al. [2006]
}}
}}

=Organic aerosols (OA)=
Team members: [[Yumin LI]], [[Tzung-May FU]]

{{Box|type=l_red_light|text='''Impacts of chemical degradation on the global budget of atmospheric levoglucosan and its use as a biomass burning tracer'''

{{HideProject|
{{:Papers:Li_et_al_2021}}
}}
}}

{{Box|type=l_red_light|text='''Parameterized yields of semi-volatile products from isoprene oxidation under different NOx levels:impacts of chemical aging and wall-loss of reactive gases'''

{{HideProject|
{{:Papers:Xing_et_al_2018}}
}}
}}

{{Box|type=l_red_light|text='''Global budgets of atmospheric glyoxal and methylglyoxal, and implications for formation of secondary organic aerosols'''

{{HideProject|
{{:Papers:Fu_et_al_2008}}
}}
}}

{{Box|type=l_red_light|text='''Carbonaceous aerosols in China: top-down constraints on primary sources and estimation of secondary contribution'''

{{HideProject|
{{:Papers:Fu_et_al_2012}}
}}
}}

{{Box|type=l_red_light|text='''Sources of secondary organic aerosols in the Pearl River Delta region in fall: Contributions from the aqueous reactive uptake of dicarbonyls'''

{{HideProject|
{{:Papers:Li_et_al_2013}}
}}
}}

{{Box|type=l_red_light|text='''Seasonal and spatial variability of the OM/OC mass ratios and high regional correlation between oxalic acid and zinc in Chinese urban organic aerosols'''

{{HideProject|
{{:Papers:Xing_et_al_2013}}
}}
}}

{{Box|type=l_red_light|text='''A new physically-based parameterization scheme for organic aerosol size evolution'''

{{HideProject|
Xing et al., in progress.
}}
}}

=Air-sea exchange of organic materials=
Team members: [[Cenlin HE]], [[Tzung-May FU]]

The ocean can act both as a source and a sink of atmospheric organic material. The air/sea exchange of organic materials is complexly regulated by both physical and biological conditions at the interface and poorly understood. We developed a new conceptual model to account for these physical and biological processes, including the presence of microfilms, production/consumption of organic matter by marine life, and other photochemical processes.

{{Box|type=l_red_light|text='''Air-Sea Exchange of Volatile Organic Compounds: A New Model with Microlayer Effects'''

{{HideProject|
{{:Papers:He_and_Fu_2012}}
}}
}}

Papers: Feng et al 2023

2023-10-27T12:33:10Z

Atomoschem:

Papers: Feng et al 2023

2023-10-27T12:32:43Z

Atomoschem:

[[Image:Feng et al 2023 ship COVID.jpeg|center|500px|Ship Emission]]

[[Image:Group_outing_202108.jpg|center|500px|Group outing to Shenzhen Zoo in August 2021.]]

'''Abstract |''' In early 2020, two unique events perturbed ship emissions of pollutants around Southern China, proffering insights into the impacts of ship emissions on regional air quality: the decline of ship activities due to COVID-19 and the global enforcement of low-sulfur (<0.5%) fuel oil for ships. In January and February 2020, estimated ship emissions of NOx, SO2, and primary PM2.5 over Southern China dropped by 19, 71, and 58%, respectively, relative to the same period in 2019. The decline of ship NOx emissions was mostly over the coastal waters and inland waterways of Southern China due to reduced ship activities. The decline of ship SO2 and primary PM2.5 emissions was most pronounced outside the Chinese Domestic Emission Control Area due to the switch to low-sulfur fuel oil there. Ship emission reductions in early 2020 drove 16 to 18% decreases in surface NO2 levels but 3.8 to 4.9% increases in surface ozone over Southern China. We estimated that ship emissions contributed 40% of surface NO2 concentrations over Guangdong in winter. Our results indicated that future abatements of ship emissions should be implemented synergistically with reductions of land-borne anthropogenic emissions of nonmethane volatile organic compounds to effectively alleviate regional ozone pollution.

'''Publication |''' '''Feng, X.''', '''Ma, Y.''', '''Lin, H.''', '''Fu, T.-M.*''', Zhang, Y., '''Wang, X.''', '''Zhang, A.''', Yuan, Y., Han, Z., Mao, J., Wang, D., Zhu, L., '''Wu, Y.''', Li, Y., Yang, X. (2023), Impacts of ship emissions on air quality in Southern China: opportunistic insights from the abrupt emission changes in early 2020, ''Environmental Science & Technology'', doi:10.1021/acs.est.3c04155. [https://atmoschem.org.cn/papers/1Feng_et_al_2023-Impacts-of-ship-emissions-on-air-quality-in-southern-china-opportunistic-insights-from-the-abrupt.pdf PDF] [https://pubs.acs.org/doi/epdf/10.1021/acs.est.3c04155 Full text]

People

2023-10-27T12:31:49Z

Atomoschem:

[[Image:group202207.jpg|center|500px|Saying goodbye to Zhanzhou and welcoming Wei, Xiaolin, and Jiashu (July 2022).]]

[[Image:Group_outing_202108.jpg|center|500px|Group outing to Shenzhen Zoo in August 2021.]]

=Current members=
*[[Tzung-May FU]] 傅宗玫: Group Leader

*[[Jiongkai CHEN]] 陈炯恺: Master student

*[[Yiheng CHEN]] 陈以恒: PhD student (joint program with HK UST)

*[[Wai-Chi CHENG]] 郑伟智: Research Assistant Professor

*[[Ao DING]] 丁傲: Research assistant

*[[Hanrui DUAN]] 段涵睿: PhD student (joint program with HK Chinese U)

*[[Huiran FENG]] 冯汇然: PhD student

*[[Tianci JIANG]] 姜天赐: Master student

*[[Yue HOU]] 侯岳: Master student

*[[Yumin LI]] 李钰敏: PhD student (joint program with HK UST)

*[[Dongli LIU]] 刘冬丽: Group secretary

*[[Jiajia MO]] 莫佳佳: Research Assistant

*[[Xingyu NAN]] 南星宇: Master student

*[[Wei TAO]] 陶玮: Research Assistant Professor

*[[Xiaolin WANG]] 王晓琳: PhD student

*[[Hanqing WU]] 吴涵清: Research Assistant

*[[Wenlu WU]] 吴雯潞: PhD student (joint program with Leeds)

*[[Luyu XIAHOU]] 夏侯露钰: Master student

*[[Enyu XIONG]] 熊恩煜: PhD student (joint program with HK PolyU)

*[[Wenyu YIN]] 尹文钰: Research Assistant

*[[Aoxing ZHANG]] 张傲星: Research Assistant Professor

=Alumni=
*[[Hansen CAO]] 曹汉森: PhD student. Now postdoc at University of Colorado.
*[[Jinxuan CHEN]] 陈晋轩: Master's student. Now PhD student at Max Planck Institute.
*[[Yedong CHEN]] 陈冶冬: Undergraduate student. Now Mmaster student at University of Wisconsin - Madison.
*[[Yijie CHEN]] 陈艺捷：Undergraduate student.
*[[Rong DAI]] 戴容: Undergraduate student. Now PhD student at Peking University.
*[[Xu FENG]] 冯旭: PhD student. Now postdoc at Harvard
*[[Bowen GE]] 葛博文: Undergraduate student.
*[[Lei GENG]] 耿磊: Undergraduate student. Now PhD student at PKU.
*[https://staff.ucar.edu/users/cenlinhe Cenlin HE] 贺涔霖: Undergraduate (2011-2012). PhD from UCLA. Now postdoc at NCAR.
*[[Yue JIAN]] 简悦: Master's student. Now staff at private environmental consulting company.
*[[Zhongjing JIANG]] 姜中景：PhD student.
*[[Wanying KANG]] 康婉莹: Undergraduate (2013-2014). Now Assistant Professor at MIT.
*[[Nan LI]] 李楠: PhD student co-adviced PhD student at the Institute of Earth's Environment, CAS. Now Professor at NUIST.
*Yinan LI 李益楠: Undergraduate student. Now PhD student at PLA Univ of Sci. & Tech.
*Zongheng LI 李纵横: Undergraduate student. Now PhD student at PLA Univ of Sci. & Tech.
*[https://scholar.harvard.edu/hplin/home Haipeng LIN] 林海芃: Undergraduate student. Now PhD student at Harvard.
*[[Jing LIU]] 刘晶: Undergraduate student
*[[Junzhe LIU]] 刘浚哲：Undergraduate student
*[[Xin LONG]] 龙鑫: Research Assistant Professor
*[[Yaping MA]] 马亚平: PhD student. Now staff at National Climate Center.
*[[Heng TIAN]] 田亨: PhD student. Now staff at private wind power company.
*[[Yujie WU]] 吴育杰: Research Assistant. Now PhD student at Princeton.
*[[Li XING]] 邢莉: PhD student. Now Associate Professor at Shaanxi Normal University.
*[[Wei XU]] 徐伟: Master's.
*[[Yanzhou YANG]] 杨颜舟：Undergraduate student. Now master student at Beijing Normal University.
*[[Shun Yao]] 姚舜：Research Assistant. Now PhD student at Nankai University.
*[[Jiashu YE]] 叶嘉澍: Research Assistant. Now PhD student at HKUST-Guangzhou.
*Qing YE 叶清: Undergraduate student. PhD from Carnegie-Mellon Univ. Now Postdoc at MIT.
*[[Lijuan ZHANG]] 张丽娟: PhD student. Now staff at Shanghai Meteorological Bureau.
*[[Meiqing ZHANG]] 张梅清: Group secretary
*[http://environment.yale.edu/unger-group/people/zheng/ Yiqi ZHENG] 郑一琦: Undergraduate student. PhD from Yale. Now Postdoc at Univ of Alaska.

Papers: Feng et al 2023

2023-10-27T12:26:03Z

Atomoschem:

[[Image:Feng et al 2023 ship COVID.jpeg (file)|center|500px|]]

File:Feng et al 2023 ship COVID.jpeg

'''Abstract |''' In early 2020, two unique events perturbed ship emissions of pollutants around Southern China, proffering insights into the impacts of ship emissions on regional air quality: the decline of ship activities due to COVID-19 and the global enforcement of low-sulfur (<0.5%) fuel oil for ships. In January and February 2020, estimated ship emissions of NOx, SO2, and primary PM2.5 over Southern China dropped by 19, 71, and 58%, respectively, relative to the same period in 2019. The decline of ship NOx emissions was mostly over the coastal waters and inland waterways of Southern China due to reduced ship activities. The decline of ship SO2 and primary PM2.5 emissions was most pronounced outside the Chinese Domestic Emission Control Area due to the switch to low-sulfur fuel oil there. Ship emission reductions in early 2020 drove 16 to 18% decreases in surface NO2 levels but 3.8 to 4.9% increases in surface ozone over Southern China. We estimated that ship emissions contributed 40% of surface NO2 concentrations over Guangdong in winter. Our results indicated that future abatements of ship emissions should be implemented synergistically with reductions of land-borne anthropogenic emissions of nonmethane volatile organic compounds to effectively alleviate regional ozone pollution.

'''Publication |''' '''Feng, X.''', '''Ma, Y.''', '''Lin, H.''', '''Fu, T.-M.*''', Zhang, Y., '''Wang, X.''', '''Zhang, A.''', Yuan, Y., Han, Z., Mao, J., Wang, D., Zhu, L., '''Wu, Y.''', Li, Y., Yang, X. (2023), Impacts of ship emissions on air quality in Southern China: opportunistic insights from the abrupt emission changes in early 2020, ''Environmental Science & Technology'', doi:10.1021/acs.est.3c04155. [https://atmoschem.org.cn/papers/1Feng_et_al_2023-Impacts-of-ship-emissions-on-air-quality-in-southern-china-opportunistic-insights-from-the-abrupt.pdf PDF] [https://pubs.acs.org/doi/epdf/10.1021/acs.est.3c04155 Full text]

Papers: Feng et al 2023

2023-10-27T12:24:48Z

Atomoschem:

[[Image:group202207.jpg|center|500px|Saying goodbye to Zhanzhou and welcoming Wei, Xiaolin, and Jiashu (July 2022).]]

'''Abstract |''' In early 2020, two unique events perturbed ship emissions of pollutants around Southern China, proffering insights into the impacts of ship emissions on regional air quality: the decline of ship activities due to COVID-19 and the global enforcement of low-sulfur (<0.5%) fuel oil for ships. In January and February 2020, estimated ship emissions of NOx, SO2, and primary PM2.5 over Southern China dropped by 19, 71, and 58%, respectively, relative to the same period in 2019. The decline of ship NOx emissions was mostly over the coastal waters and inland waterways of Southern China due to reduced ship activities. The decline of ship SO2 and primary PM2.5 emissions was most pronounced outside the Chinese Domestic Emission Control Area due to the switch to low-sulfur fuel oil there. Ship emission reductions in early 2020 drove 16 to 18% decreases in surface NO2 levels but 3.8 to 4.9% increases in surface ozone over Southern China. We estimated that ship emissions contributed 40% of surface NO2 concentrations over Guangdong in winter. Our results indicated that future abatements of ship emissions should be implemented synergistically with reductions of land-borne anthropogenic emissions of nonmethane volatile organic compounds to effectively alleviate regional ozone pollution.

'''Publication |''' '''Feng, X.''', '''Ma, Y.''', '''Lin, H.''', '''Fu, T.-M.*''', Zhang, Y., '''Wang, X.''', '''Zhang, A.''', Yuan, Y., Han, Z., Mao, J., Wang, D., Zhu, L., '''Wu, Y.''', Li, Y., Yang, X. (2023), Impacts of ship emissions on air quality in Southern China: opportunistic insights from the abrupt emission changes in early 2020, ''Environmental Science & Technology'', doi:10.1021/acs.est.3c04155. [https://atmoschem.org.cn/papers/1Feng_et_al_2023-Impacts-of-ship-emissions-on-air-quality-in-southern-china-opportunistic-insights-from-the-abrupt.pdf PDF] [https://pubs.acs.org/doi/epdf/10.1021/acs.est.3c04155 Full text]

2023-10-27T08:59:44Z

Atomoschem:

Papers: Feng et al 2023

2023-10-27T08:58:32Z

Atomoschem:

[[Feng_et_al_2023_ship_COVID.jpeg|center|500px|Feng2023.]]

'''Abstract |''' In early 2020, two unique events perturbed ship emissions of pollutants around Southern China, proffering insights into the impacts of ship emissions on regional air quality: the decline of ship activities due to COVID-19 and the global enforcement of low-sulfur (<0.5%) fuel oil for ships. In January and February 2020, estimated ship emissions of NOx, SO2, and primary PM2.5 over Southern China dropped by 19, 71, and 58%, respectively, relative to the same period in 2019. The decline of ship NOx emissions was mostly over the coastal waters and inland waterways of Southern China due to reduced ship activities. The decline of ship SO2 and primary PM2.5 emissions was most pronounced outside the Chinese Domestic Emission Control Area due to the switch to low-sulfur fuel oil there. Ship emission reductions in early 2020 drove 16 to 18% decreases in surface NO2 levels but 3.8 to 4.9% increases in surface ozone over Southern China. We estimated that ship emissions contributed 40% of surface NO2 concentrations over Guangdong in winter. Our results indicated that future abatements of ship emissions should be implemented synergistically with reductions of land-borne anthropogenic emissions of nonmethane volatile organic compounds to effectively alleviate regional ozone pollution.

'''Publication |''' '''Feng, X.''', '''Ma, Y.''', '''Lin, H.''', '''Fu, T.-M.*''', Zhang, Y., '''Wang, X.''', '''Zhang, A.''', Yuan, Y., Han, Z., Mao, J., Wang, D., Zhu, L., '''Wu, Y.''', Li, Y., Yang, X. (2023), Impacts of ship emissions on air quality in Southern China: opportunistic insights from the abrupt emission changes in early 2020, ''Environmental Science & Technology'', doi:10.1021/acs.est.3c04155. [https://atmoschem.org.cn/papers/1Feng_et_al_2023-Impacts-of-ship-emissions-on-air-quality-in-southern-china-opportunistic-insights-from-the-abrupt.pdf PDF] [https://pubs.acs.org/doi/epdf/10.1021/acs.est.3c04155 Full text]

Papers: Feng et al 2023

2023-10-27T08:53:51Z

Atomoschem:

[[Image:Feng_et_al_2023_ship_COVID.jpeg]]

'''Abstract |''' In early 2020, two unique events perturbed ship emissions of pollutants around Southern China, proffering insights into the impacts of ship emissions on regional air quality: the decline of ship activities due to COVID-19 and the global enforcement of low-sulfur (<0.5%) fuel oil for ships. In January and February 2020, estimated ship emissions of NOx, SO2, and primary PM2.5 over Southern China dropped by 19, 71, and 58%, respectively, relative to the same period in 2019. The decline of ship NOx emissions was mostly over the coastal waters and inland waterways of Southern China due to reduced ship activities. The decline of ship SO2 and primary PM2.5 emissions was most pronounced outside the Chinese Domestic Emission Control Area due to the switch to low-sulfur fuel oil there. Ship emission reductions in early 2020 drove 16 to 18% decreases in surface NO2 levels but 3.8 to 4.9% increases in surface ozone over Southern China. We estimated that ship emissions contributed 40% of surface NO2 concentrations over Guangdong in winter. Our results indicated that future abatements of ship emissions should be implemented synergistically with reductions of land-borne anthropogenic emissions of nonmethane volatile organic compounds to effectively alleviate regional ozone pollution.

'''Publication |''' '''Feng, X.''', '''Ma, Y.''', '''Lin, H.''', '''Fu, T.-M.*''', Zhang, Y., '''Wang, X.''', '''Zhang, A.''', Yuan, Y., Han, Z., Mao, J., Wang, D., Zhu, L., '''Wu, Y.''', Li, Y., Yang, X. (2023), Impacts of ship emissions on air quality in Southern China: opportunistic insights from the abrupt emission changes in early 2020, ''Environmental Science & Technology'', doi:10.1021/acs.est.3c04155. [https://atmoschem.org.cn/papers/1Feng_et_al_2023-Impacts-of-ship-emissions-on-air-quality-in-southern-china-opportunistic-insights-from-the-abrupt.pdf PDF] [https://pubs.acs.org/doi/epdf/10.1021/acs.est.3c04155 Full text]

Papers: Feng et al 2023

2023-10-27T08:53:34Z

Atomoschem:

[Image:Feng_et_al_2023_ship_COVID.jpeg]

'''Abstract |''' In early 2020, two unique events perturbed ship emissions of pollutants around Southern China, proffering insights into the impacts of ship emissions on regional air quality: the decline of ship activities due to COVID-19 and the global enforcement of low-sulfur (<0.5%) fuel oil for ships. In January and February 2020, estimated ship emissions of NOx, SO2, and primary PM2.5 over Southern China dropped by 19, 71, and 58%, respectively, relative to the same period in 2019. The decline of ship NOx emissions was mostly over the coastal waters and inland waterways of Southern China due to reduced ship activities. The decline of ship SO2 and primary PM2.5 emissions was most pronounced outside the Chinese Domestic Emission Control Area due to the switch to low-sulfur fuel oil there. Ship emission reductions in early 2020 drove 16 to 18% decreases in surface NO2 levels but 3.8 to 4.9% increases in surface ozone over Southern China. We estimated that ship emissions contributed 40% of surface NO2 concentrations over Guangdong in winter. Our results indicated that future abatements of ship emissions should be implemented synergistically with reductions of land-borne anthropogenic emissions of nonmethane volatile organic compounds to effectively alleviate regional ozone pollution.

'''Publication |''' '''Feng, X.''', '''Ma, Y.''', '''Lin, H.''', '''Fu, T.-M.*''', Zhang, Y., '''Wang, X.''', '''Zhang, A.''', Yuan, Y., Han, Z., Mao, J., Wang, D., Zhu, L., '''Wu, Y.''', Li, Y., Yang, X. (2023), Impacts of ship emissions on air quality in Southern China: opportunistic insights from the abrupt emission changes in early 2020, ''Environmental Science & Technology'', doi:10.1021/acs.est.3c04155. [https://atmoschem.org.cn/papers/1Feng_et_al_2023-Impacts-of-ship-emissions-on-air-quality-in-southern-china-opportunistic-insights-from-the-abrupt.pdf PDF] [https://pubs.acs.org/doi/epdf/10.1021/acs.est.3c04155 Full text]

2023-10-26T03:11:34Z

Atomoschem: /* Published / In press */

=Published / In press=
#'''Feng, X.''', '''Ma, Y.''', '''Lin, H.''', '''Fu, T.-M.*''', Zhang, Y., '''Wang, X.''', '''Zhang, A.''', Yuan, Y., Han, Z., Mao, J., Wang, D., Zhu, L., '''Wu, Y.''', Li, Y., Yang, X. (2023), Impacts of ship emissions on air quality in Southern China: opportunistic insights from the abrupt emission changes in early 2020, ''Environmental Science & Technology'', doi:10.1021/acs.est.3c04155. [https://atmoschem.org.cn/papers/1Feng_et_al_2023-Impacts-of-ship-emissions-on-air-quality-in-southern-china-opportunistic-insights-from-the-abrupt.pdf PDF] [https://pubs.acs.org/doi/epdf/10.1021/acs.est.3c04155 Full text].
#'''Li, Y.''', '''Fu, T.-M.*''', Yu, J. Z.*, Yu, X., Chen, Q., Miao, R., Zhou, Y., '''Zhang, A.''', Ye, J., Yang, X., Tao, S., Liu, H., Yao, W. (2023), Dissecting the contributions of organic nitrogen aerosols to global atmospheric nitrogen deposition and implications for ecosystems, ''National Science Review'', nwad244, doi:10.1093/nsr/nwad244. [https://atmoschem.org.cn/papers/2Li_et_al_2023_National_Science_Review_Dissecting.pdf PDF] [https://doi.org/10.1093/nsr/nwad244 Full text]
# Zhai, J., Yu, G., Zhang, J., Shi, S., Yuan, Y., Jiang, S., Xing, C., Cai, B., Zeng, Y., Wang, Y., Zhang, A., Zhang, Y., '''Fu, T.-M.''', Zhu, L., Shen, H., Ye, J., Wang, C., Tao, S., Li, M., Zhang, Y.*, Yang, X.* (2023), Impact of ship emissions on air quality in the Greater Bay Area in China under the Latest Global Marine Fuel Regulation, ''Enviornmental Science & Technology'', doi:10.1021/acs.est.3c03950. [https://atmoschem.org.cn/papers/3Zhai_et_al_2023_EST_Impact-of-ship-emissions.pdf PDF] [https://pubs.acs.org/doi/10.1021/acs.est.3c03950 Full text].
# 刘婵芳, '''张傲星*''', 房庆, 叶毓婧, 杨红龙, '''陈炯恺''', '''吴雯潞''', '''侯岳''', '''莫佳佳''', '''傅宗玫'''. (2023), 深圳市2022年春季新冠疫情管控期间空气质量分析[J/OL], ''环境科学'', 44(6):3117-3129, doi:10.13227/j.hjkx.202205313. [https://atmoschem.org.cn/papers/4Shenzhen_2022_Covid_HuanJingKeXue.pdf PDF] [https://www.hjkx.ac.cn/hjkx/ch/reader/view_abstract.aspx?flag=1&file_no=20230612&journal_id=hjkx Full text]
# '''Zhang, A.''', '''Fu, T.-M.*''', '''Feng, X.''', Guo, J., Liu, C., '''Chen, J.''', '''Mo, J.''', Zhang, X., '''Wang, X.''', '''Wu, W.''', '''Hou, Y.''', Yang, H., Lu, C. (2023), Deep learning-based ensemble forecasts and predictability assessments for surface ozone pollution. ''Geophysical Research Letters'', e2022GL102611, doi:10.1029/2022GL102611. [https://atmoschem.org.cn/papers/5GRL_2023_Zhang_Deep_Learning_Forecasts.pdf PDF] [https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2022GL102611 Full text]
# '''Wang, X.''', '''Fu, T.-M.*''', Zhang, L.*, Lu, X., Liu, X., Amnuaylojaroen, T., Latif, M. T., '''Ma, Y.''', '''Zhang, L.''', '''Feng, X.''', Zhu, L., Shen, H., Yang, X. (2022), Rapidly changing emissions drove substantial surface and tropospheric ozone increases over Southeast Asia, ''Geophysical Research Letters'', e2022GL100223, doi:10.1029/2022GL100223. [https://atmoschem.org.cn/papers/Wang_et_al_2022_Geophysical_Research_Letters.pdf PDF] [https://agupubs.onlinelibrary.wiley.com/doi/epdf/10.1029/2022GL100223 Full text].
# Xing, C., Wang, Y., Yang, X., Zeng, Y., Zhai, J., Cai, B., Zhang, A., '''Fu, T.-M.''', Zhu, L., Li, Y., Wang, X., Zhang, Y. (2022), Seasonal variation of driving factors of ambient PM2.5 oxidative potential in Shenzhen, China, ''Science of the Total Environment'', 862(1), doi:10.1016/j.scitotenv.2022.160771.[https://atmoschem.org.cn/papers/Xing_et_al_2022_Science_of_the_Total_Environment.pdf PDF] [https://www.sciencedirect.com/science/article/pii/S0048969722078743 Full text].
# Zhai, J., Yang, X., Li, L., Ye, X., Chen, J., '''Fu, T.-M.''', Zhu, L., Shen, H., Ye, J., Wang, C., Tao S. (2022). Direct observation of the transitional stage of mixing-state-related absorption enhancement for atmospheric black carbon. ''Geophysical Research Letters'', 49, e2022GL101368, doi:10.1029/2022GL101368. [https://atmoschem.org.cn/papers/Zhai_et_al_2022_Geophysical_Research_Lett.pdf PDF] [https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2022GL101368 Full text].
# Pu, D., Zhu, L., De Smedt, I., Li, X., Sun, W., Wang, D., Liu, S., Li, J., Shu, L., Chen, Y., Sun, S., Zuo, X., Fu, W., Xu, P., Yang, X., '''Fu, T.-M.''' (2022), Response of anthropogenic volatile organic compound emissions to urbanization in Asia probed with TROPOMI and VIIRS satellite observations, ''Geophysical Research Letters'', e2022GL099470, doi:10.1029/2022GL099470. [https://atmoschem.org.cn/papers/Pu_et_al_2022_Geophysical_Research_Letters.pdf PDF ] [https://agupubs.onlinelibrary.wiley.com/doi/10.1029/2022GL099470 Full text].
# '''Long, X.''', '''Fu, T.-M.*''', Yang, X., Tang, Y., Zheng, Y., Zhu, L., Shen, H., Ye, J., Wang, C., Wang, T., Li, B. (2022), Efficient atmospheric transport of microplastics over Asia and adjacent oceans, ''Enviornmental Science & Technology'', 56(10), 6243–6252, doi:10.1021/acs.est.1c07825.[https://atmoschem.org.cn/papers/Long_et_al_2022_Environmental_Science_and_Technology.pdf PDF ] [https://pubs.acs.org/doi/10.1021/acs.est.1c07825 Full text].
#Shu, L., Zhu, L., Bak, J., Zoogman, P., Han, H., Long, X., Bai, B., Liu, S., Wang, D., Sun, W., Pu, D., Chen, Y., Li, X., Sun, S., Li, J., Yang, X., '''Fu, T.-M.''' (2022), Improved Ozone Simulation in East Asia via Assimilating Observations from the First Geostationary Air-quality Monitoring Satellite: Insights from an Observing System Simulation Experiment, ''Atmospheric Environment'', 274, 119003, doi:10.1016/j.atmosenv.2022.119003. [https://atmoschem.org.cn/papers/Shu_et_al_2022_Atmospheric_Environment.pdf PDF ] [https://www.sciencedirect.com/science/article/pii/S1352231022000681?via%3Dihub Full text].
# Xu, X., '''Feng, X.''', '''Lin, H.''', Zhang, P., Huang, S., Song, Z., Peng, Y., '''Fu, T.-M.''', Zhang, Y. (2022), Modeling the high-mercury wet deposition in the southeastern US with WRF-GC-Hg v1.0, ''Geoscientific Model Development'', 15, 3845–3859, doi:10.5194/gmd-15-3845-2022.[https://atmoschem.org.cn/papers/Xu_et_al_2022_Geoscientific_Model_Development.pdf PDF ] [https://gmd.copernicus.org/articles/15/3845/2022/ Full text].
# Zhai, J., Yang, X., Li, L., Bai, B., Liu, P., Huang, Y., '''Fu, T.-M.''', Zhu, L., Zeng, Z., Tao, S., Lu, X., Ye, X., Wang, X., Wang, L., Chen, J. (2022), Absorption enhancement of black carbon aerosols constrained by mixing-state heterogeneity, ''Environmental Science & Technology'', 56(3), 1586–1593, doi:10.1021/acs.est.1c06180. [https://atmoschem.org.cn/papers/Zhai_et_al_2022_Environmental_Science_and_Technology.pdf PDF ] [https://pubs.acs.org/doi/10.1021/acs.est.1c06180 Full text]
# Xing, L., '''Fu, T.-M.''', Liu, T., Qin, Y., Zhou, L., Chan, C. K., Guo, H., Yao, D., Duan, K. (2022), Estimating organic aerosol emissions from cooking in winter over the Pearl River Delta region, China, ''Environmental Pollution'', 292(A), 118266, doi:10.1016/j.envpol.2021.118266. [https://atmoschem.org.cn/papers/Xing_et_al_2021_Environmental_Pollution.pdf PDF ] [https://www.sciencedirect.com/science/article/pii/S0269749121018480 Full text]
# Cao, H., Henze, D. K., Cady-Pereira, K., McDonald, B. C., Harkins, C., Sun, K., Bowman, K. W., '''Fu, T.-M.''', Nawaz, M. O. (2021), COVID-19 lockdowns afford the first satellite-based confirmation that vehicles are an under-recognized source of urban NH3 pollution in Los Angeles, ''Environmental Science & Technology Letters'', 9(1), 3-9, doi:10.1021/acs.estlett.1c00730. [https://atmoschem.org.cn/papers/Cao_et_al_2021_Environmental_Science_and_Technology_Letters.pdf PDF ] [https://pubs.acs.org/doi/10.1021/acs.estlett.1c00730 Full text]
# '''Feng, X.''', '''Lin, H.''', '''Fu, T.-M.*''', Sulprizio, M. P., Zhuang, J., Jacob, D. J., '''Tian, H.''', '''Ma, Y.''', '''Zhang, L.''', '''Wang, X.''', Chen, Q., Han, Z. (2021), WRF-GC (v2.0): online two-way coupling of WRF (v3.9.1.1) and GEOS-Chem (v12.7.2) for modeling regional atmospheric chemistry-meteorology interactions, ''Geosci. Model. Dev.'', 14，3741-3768，doi:10.5194/gmd-14-3741-2021. [https://atmoschem.org.cn/papers/Feng_et_al_2021_Geoscientific_Model_Development.pdf PDF ] [https://gmd.copernicus.org/articles/14/3741/2021/ Full text]
# '''Wang, X.''', '''Fu, T.-M.*''', Zhang, L.*, '''Cao, H.''', Zhang, Q. Ma, H., Shen, L., Evans, M., Ivatt, P., Lu., X., Chen, Y., '''Zhang, L.''', '''Feng, X.''', Yang, X., Zhu, L., Henze, D. (2021), Sensitivities of ozone air pollution in the Beijing-Tianjin-Hebei area to local and upwind precursor emissions using adjoint modelling, ''Environmental Science & Technology'', 55(9),5752-5762, doi:10.1021/acs.est.1c00131. [https://atmoschem.org.cn/papers/Wang_et_al_2021_Environmental_Science_and_Technology.pdf PDF ] [https://doi.org/10.1021/acs.est.1c00131 Full text].
# '''Li, Y.''', '''Fu, T.-M.*''', Yu, J. Z.*, '''Feng, X.''', '''Zhang, L.''', Chen, J., Boreddy, S. K. R., Kawamura, K., Fu, P., Yang, X., Zhu, L., Zeng, Z. (2021), Impacts of chemical degradation on the global budget of atmospheric levoglucosan and its use as a biomass burning tracer, ''Environmental Science & Technology'', 55(8), 5525-5536, doi:10.1021/acs.est.0c07313. [https://atmoschem.org.cn/papers/li_et_al_2021_Environmental_Science_and_Technology.pdf PDF ] [https://doi.org/10.1021/acs.est.0c07313 Full text].
# Zhang, R., Gen, M. '''Fu, T.-M.''', Chan, C. (2021), Production of formate via oxidation of glyoxal promoted by particulate nitrate photolysis, ''Environmental Science & Technology'', 55(9), 5711-5720, doi:10.1021/acs.est.0c081999. [https://atmoschem.org.cn/papers/Zhang_et_al_2021_Environmental_Science_and_Technology.pdf PDF ] [https://doi.org/10.1021/acs.est.0c08199 Full text]
# Hu, S., Wang, D., Wu, J., Zhou, L., '''Feng, X.''', '''Fu, T.-M.''', Yang, X., Ziegler, A. D., Zeng, Z. (2021), Aerosol presence reduces the diurnal temperature range: an interval when the COVID-19 pandemic reduced aerosols revealing the effect on climate, ''Environmental Science: Atmospheres'', doi:10.1039/D1EA00021G. [https://atmoschem.org.cn/papers/Hu_et_al_2021_Environmental_Science_Atmospheres.pdf PDF ] [https://pubs.rsc.org/vi/content/articlelanding/2021/ea/d1ea00021g#! Full text]
# Sun, W., Zhu, L., De Smedt, I., Bai, B., Pu, D., Chen, Y., Shu, L., Wang, D., '''Fu, T.-M.''', Wang, X., and Yang, X. (2021): Global Significant Changes in Formaldehyde (HCHO) Columns Observed from Space at the Early Stage of the COVID-19 Pandemic, ''Geophys. Res. Lett'', doi:10.1029/2020GL091265. [https://atmoschem.org.cn/papers/Sun_et_al_2021_Geophys_Res_Lett.pdf PDF ] [https://doi.org/10.1029/2020GL091265 Full text]
# Fan, W., Liu, Y., Chappell, A. Dong, L., Xu, R. Ekstrom, M., '''Fu., T.-M.''', Zeng Z. (2021), Evaluation of global reanalysis land surface wind speed trends to support wind energy development using in situ observations, ''J. Applied Meteorology and Climatology'', 60(1), 33-50, doi:10.1175/JAMC-D-20-0037.1. [https://atmoschem.org.cn/papers/Fan_et_al_2021_J_Applied_Meteorology_and_Climatology.pdf PDF ] [https://journals.ametsoc.org/view/journals/apme/60/1/jamc-d-20-0037.1.xml Full text]
# '''Lin, H.''', '''Feng, X.''', '''Fu, T.-M.*''', '''Tian, H.''', '''Ma, Y.''', '''Zhang, L.''', Jacob, D.J., Yantosca, R.M., Sulprizio, M.P., Lundgren, E.W., Zhuang, J., Zhang, Q., Lu, X., Zhang, L., Shen, L., Guo, J., Eastham, S.D., Keller, C.A. (2020), WRF-GC (v1.0): online coupling of WRF (v3.9.1.1) and GEOS-Chem (v12.2.1) for regional atmospheric chemistry modeling – Part 1: Description of the one-way model, ''Geosci. Model Dev.'', doi:10.5194/gmd-13-3241-2020. [https://atmoschem.org.cn/papers/Lin_et_al_2020_Geoscientific_Model_Development.pdf PDF ] [https://gmd.copernicus.org/articles/13/3241/2020/gmd-13-3241-2020.html Full text]
# Elguindi, N., Granier, C., Stavrakou, S., Darras, S., Bauwens, M., '''Cao, H.''', Chen, C., Denier van der Gon, H. A. C., Dubovik, O., '''Fu, T.-M.''', Henze, D. K., Jiang, Z., Keita, S., Kuenen, J. J. P., Kurokawa, J., Liousse, C., Miyazaki, K., Muller, J.-F., Qu, Z., Solmon, F., Zheng, B. (2020), Intercomparison of magnitudes and trends in anthropogenic surface emissions from bottom-up inventories, top-down estimates, and emission scenarios. ''Earth's Future'',doi：10.1029/2020EF001520[https://atmoschem.org.cn/papers/N.Elguindi_et_al_Earth's_Future.pdf PDF ] [https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2020EF001520 Full text]
# '''Ma, Y.''', '''Fu, T.-M.*''', '''Tian, H.''', Gao, J., Hu, M., Guo, J., Zhang, Y., Sun, Y., '''Zhang, L.''', Yang, X., Wang, X. (2020), Emergency Response Measures to Alleviate a Severe Haze Pollution Event in Northern China during December 2015: Assessment of Effectiveness. ''Aerosol and Air Quality Research'', doi:10.4209/aaqr.2019.09.0442. [https://atmoschem.org.cn/papers/Ma_et_al_2020_Aerosol_and_Air_Quality_Research.pdf PDF] [https://aaqr.org/articles/aaqr-19-09-oa-0442 Full Text]
# Wang, X., Ye, X., Chen, J., Wang, X., Yang, X., '''Fu, T.-M.''', Zhu, L., Liu, C. (2020), Direct links between hygroscopicity and mixing state of ambient aerosols: estimating particle hygroscopicity from their single-particle mass spectra, ''Atmos. Chem. Phys.'', 20, 6273–6290, doi:10.5194/acp-20-6273-2020. [https://atmoschem.org.cn/papers/Wang_et_al_2020_Atmospheric_Chemistry_and_Physics.pdf PDF] [https://acp.copernicus.org/articles/20/6273/2020/ Full Text]
#Xu, X., Lu, X., Li, X. Liu, Y., Wang, X., Chen, H., Chen, J., Yang, X., '''Fu, T.-M.''', Zhao, Q., Fu, Q. (2020), ROS-generation potential of Humic-like substances (HULIS) in ambient PM2.5 in urban Shanghai: Association with HULIS concentration and light absorbance, ''Chemosphere'', 256, 127050, doi: 10.1016/j.chemosphere.2020.127050. [https://atmoschem.org.cn/papers/Xu-et-al-2020-Chemosphere.pdf PDF ][https://www.sciencedirect.com/science/article/pii/S0045653520312431 Full Text]
# Zhang, R., Zhang, Y., '''Lin, H.''', '''Feng, X.''', '''Fu, T.-M.''', Wang, Y. (2020), NOx emission reduction and recovery during COVID-19 in East China, ''Atmosphere'', 11(4), 433, doi:10.3390/atmos11040433. [https://atmoschem.org.cn/papers/Zhang-et-al-2020-Atmosphere.pdf PDF ] [https://www.mdpi.com/2073-4433/11/4/433 Full Text]
# '''Jiang, Z.''', Jolleys, M. D., '''Fu, T.-M.*''', Palmer, P. I.*, '''Ma, Y.''', '''Tian, H.''', Li, J., Yang, X. (2020), Spatiotemporal and probability variations of surface PM2.5 over China between 2013 and 2019 and the associated changes in health risks: an integrative observation and model analyses, ''Science of the Total Environment'', 723, doi:10.1016/j.scitotenv.2020.137896. [https://atmoschem.org.cn/papers/Jiang-et-al-2020-Science-of-the-Total-Environment.pdf PDF]
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# '''Zhang, L.''', '''Fu, T.-M.*''', '''Tian, H.''', '''Ma, Y.''', Chen, J.-P., Tsai, T.-C., Tsai, I.-C., Meng, Z., Yang, X. (2020), Anthropogenic aerosols significantly reduce mesoscale convective system occurrences and precipitation over Southern China in April, ''Geophys. Res. Lett.'', doi: 10.1029/2019GL086204. [https://atmoschem.org.cn/papers/Zhang-et-al-2020-Geophys.-Res.-Lett.pdf PDF ] [https://agupubs.onlinelibrary.wiley.com/doi/10.1029/2019GL086204 Full Text]
# Zhang*, Y., Vu, T. V., Sun, J., He, J., Shen, X., Lin, W., Zhang, X., Zhong, J., Gao, W., Wang, Y., '''Fu, T.-M.''', '''Ma., Y.''', Li, W., Shi, Z. (2020), Significant Changes in Chemistry of Fine Particles in Wintertime Beijing from 2007 to 2017: Impact of Clean Air Actions, ''Environmental Science & Technology'', doi:10.1021/acs.est.9b04678. [https://atmoschem.org.cn/papers/Zhang-et-al-2020-Environmental-Science-Technology.pdf PDF ] [https://pubmed.ncbi.nlm.nih.gov/31766848/ Full Text]
# Zhao, Y.-H., Zhang, L.*, Zhou, M., Chen, D., Lu, X., Tao, W., Liu, J.-F., '''Tian, H.''', '''Ma, Y.-P.''', '''Fu, T.-M.'''(2019), Influences of planetary boundary layer mixing parameterization on summertime surface ozone concentration and dry deposition over North China, ''Atmospheric Environment'', 218, 116950, doi:10.1016/j.atmosenv.2019.116950. [https://atmoschem.org.cn/papers/Zhao_et_al_2019_Atmospheric_Environment.pdf PDF ] [https://www.sciencedirect.com/science/article/pii/S1352231019305898 Full Text]
# Lu, X.*, Zhang, L.*, Chen, Y., Zhou, M., Zheng, B., Li, K., Liu, Y., Lin, J., '''Fu, T.-M.''', and Zhang, Q. (2019), Exploring 2016–2017 surface ozone pollution over China: source contributions and meteorological influences, ''Atmos. Chem. Phys.'', 19, 8339–8361, doi:10.5194/acp-19-8339-2019. [https://atmoschem.org.cn/papers/Lu_et_al_2019_Atmospheric_Chemistry_and_Physics.pdf PDF ] [https://acp.copernicus.org/articles/19/8339/2019/ Full Text]
# '''Fu, T.-M.*''' and '''H. Tian''' (2019), Climate change penalty to ozone air quality: review of current understandings and knowledge gaps, ''Current Pollution Reports'', 5, 159–171, doi:10.1007/s40726-019-00115-6. [https://atmoschem.org.cn/papers/Fu_et_al_2019_Current_Pollution_Reports.pdf PDF ] [https://link.springer.com/article/10.1007/s40726-019-00115-6 Full Text]
# Shen, L.*, D. J. Jacob, L. Zhu, Q. Zhang, B. Zheng, M. P. Sulprizio, K. Li, I. De Smedt, G. González Abad, '''H. Cao''', '''T.-M. Fu''', and H. Liao (2019), The 2005–2016 trends of formaldehyde columns over China observed by satellites: Increasing anthropogenic emissions of volatile organic compounds and decreasing agricultural fire emissions, ''Geophysical Research Letters'', 46. doi:10.1029/2019GL082172 [https://atmoschem.org.cn/papers/Shen_et_al_2019_Geophysical_Research_Lett.pdf PDF ] [https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2019GL082172 Full Text]
# '''Feng, X.''', '''T.-M. Fu*''', '''H. Cao''', '''H. Tian''', Q. Fan, X. Chen (2019), Neural network prediction of pollutant emissions from open burning of crop residues: application to air quality forecasts in Southern China, ''Atmospheric Environment'', 204, 22-31, doi:10.1016/j.atmosenv.2019.02.002 [https://atmoschem.org.cn/papers/Feng_et_al_2019_Atmospheric_Environment.pdf PDF ] [https://www.sciencedirect.com/science/article/pii/S135223101930086X Full Text]
# Zhou, M., L. Zhang*, D. Chen*, Y. Gu, '''T.-M. Fu''', M. Gao, Y. Zhao, X. Lu, and B. Zhao (2018), The impact of aerosol-radiation interactions on the effectiveness of emission control measures, ''Environmental Research Letters'', 14(2), 024002, doi:10.1088/1748-9326/aaf27d [https://atmoschem.org.cn/papers/Zhou_et_al_2018_Environmental_Research_Letters.pdf Full text]
# '''Cao, H.''', '''T.-M. Fu*''', L. Zhang, D. K. Henze, C. Chan Miller, C. Lerot, G. Gonzalex Abad, I. De Smedt, Q. Zhang, M. van Roosendael, K. Chance, J. Li, J. Zheng, and Y. Zhao (2018), Adjoint inversion of Chinese non-methane volatile organic compound emissions using space-based observations of formaldehyde and glyoxal, ''Atmospheric Chemistry and Physics'', 18, 15017-15046, doi:10.5194/acp-18-15017-2018. [https://atmoschem.org.cn/papers/Cao_et_al_2018_Atmospheric_Chemistry_and_Physics.pdf Full text]
# '''Xing, L.''', M. Shrivastava*, '''T.-M. Fu*''', P. Roldin, Y. Qian, L. Xu, N. L. Ng, J. Shilling, A. Zelenyuk, and C. Cappa (2018), Parameterized yields of semi-volatile products from isoprene oxidation under different NOx levels:impacts of chemical aging and wall-loss of reactive gases, ''Environmental Science and Technology'', doi: 10.1021/acs.est.8b00373. [https://atmoschem.org.cn/papers/Xing_et_al_2018_Environmental_Science_and_Technology.pdf Full text] [https://pubs.acs.org/doi/suppl/10.1021/acs.est.8b00373/suppl_file/es8b00373_si_001.pdf SI]
# Liu, M.-Y., Lin, J.-T.*, Wang, Y.-C., Sun, Y., Zheng, B., Shao, J., Chen, L.-L., Zheng, Y., Chen, J., Fu, T.-M., Yan, Y.-Y., Zhang, Q., and Wu, Z. (2018),Spatiotemporal variability of NO2 and PM2.5 over Eastern China: observational and model analyses with a novel statistical method, ''Atmospheric Chemistry and Physics'', 18, 12933-12952, doi:10.5194/acp-18-12933-2018.[https://atmoschem.org.cn/papers/Liu_et_al_2018_Atmospheric_Chemistry_and_Physics.pdf Full text]
# Chen, Q.*, '''T.-M. Fu*''', J. Hu*, Q. Ying, and L. Zhang (2017), Modelling secondary organic aerosols in China, ''National Science Review'', 4(6), 806-809, doi:10.1093/nsr/nwx143. [https://atmoschem.org.cn/papers/Chen_et_al_2017_National_Science_Review.pdf Full text]
# Li, N., J.-P. Chen*, I.-C. Tsai, Q. He, S.-Y. Chi, Y.-C. Lin, and '''T.-M. Fu''' (2016), Potential impacts of electric vehicles on air quality in Taiwan, ''Science of the Total Environment'', 566-567, 919-928, doi:10.1016/j.scitotenv.2016.05.105.[https://atmoschem.org.cn/papers/Li_et_al_2016_Science_of_the_Total_Environment.pdf Full text]
# '''Xu, W.''', '''T.-M. Fu*''', '''J. Chen''', and '''H. Tian''' (2016), Ground-based measurement and variation analysis of carbonaceous aerosols in Wuqing, ''Acta Scientiarum Naturalium Universitatis Pekinensis'', 52(3), 409-419, doi:10.13209/j.0479-8023.2015.144. (In Chinese)[https://atmoschem.org.cn/papers/Xu_et_al_2016_Acta_Scientiarum_Naturalium_Universitatis_Pekinensis.pdf Full text]
# Tsai, I.C., J.-P. Chen*, C. S.-C. Lung, '''N. Li''', W.-N. Chen, '''T.-M. Fu''', C.-C. Chang, and G.-D. Hwang (2015), Sources and formation pathways of organic aerosol in a subtropical metropolis during summer, ''Atmospheric Environment'', 117, 51-60, doi:10.1016/j.atmosenv.2015.07.005. [https://atmoschem.org.cn/papers/Tsai_et_al_2015_Atmospheric_Environment.pdf Full text]
# '''Fu, T.-M.*''', '''Y. Zheng''', F. Paulot, J. Mao, and R. M. Yantosca (2015), Positive but variable sensitivity of August surface ozone to large-scale warming in the southeast United States, ''Nature Climate Change'', 5, 454-458, doi:10.1038/nclimate2567. [https://atmoschem.org.cn/papers/Fu_et_al_2015_Nature_Climate_Change.pdf Full text]
# Zhang, L.*, L. Liu, Y. Zhao, S. Gong, X. Zhang, D. K. Henze, S. L. Capps, '''T.-M. Fu''', and Q. Zhang (2015), Source Attribution of Particulate Matter Pollution over North China with the Adjoint Method, ''Environmental Research Letters'', 10, 084011, doi:10.1088/1748-9326/10/8/084011.[https://atmoschem.org.cn/papers/Zhang_et_al_2015_Environmental_Research_Letters.pdf Full text]
# '''Xing, L.''', and '''T.-M. Fu*''' (2015), Contributions of organic aerosols to cloud condensation nuclei numbers in China, ''Acta Scientiarum Naturalium Universitatis Pekinensis'', 51(1), 13-23, doi:10.13209/j.0479-8023.2014.143. (In Chinese) [https://atmoschem.org.cn/papers/Xing_et_al_2015_Acta_Scientiarum_Naturalium_Universitatis_Pekinensis.pdf Full text]
# '''Jian, Y.''', and '''T.-M. Fu*''' (2014), Injection heights of springtime biomass burning plumes over the Peninsular Southeast Asia and their impacts on pollutant long-range transport, ''Atmos. Chem. Phys.'', 14, 3977-3989, doi:10.5194/acp-14-3977-2014. [https://atmoschem.org.cn/papers/Jian_et_al_2014_Atmospheric_Chemistry_and_Physics.pdf Full text]
# Zhang, Y., L. Qiao, '''Y. Ren''', X. Wang, M. Gao, Y. Tang, J. J. Xi, '''T.-M. Fu*''', and X. Jiang* (2013), Two dimensional barcode-inspired automatic analysis for arrayed microfluidic immunoassays, ''Biomicrofluidics'', 7, 034110, doi:10.1063/1.4811278. [https://atmoschem.org.cn/papers/Zhang_et_al_2013_Biomicrofluidics.pdf PDF]
# '''Li, N'''., '''T.-M. Fu*''', J.J. Cao*, S.C. Lee, X.-F. Huang, L.-Y. He, K.-F. Ho, J. S. Fu, and Y.-F. Lam (2013), Sources of secondary organic aerosols in the Pearl River Delta region in fall: contributions from the aqueous reactive uptake of dicarbonyls, ''Atmos. Environ.'', 76, 200-207, doi:10.1016/j.atmosenv.2012.12.005. [https://atmoschem.org.cn/papers/Li_et_al_2013_Atmospheric_Environment.pdf PDF]
# '''Xing, L.''', '''T.-M. Fu*''', J.J. Cao, S.C. Lee, G.H. Wang, K.-F. Ho, M.-C. Cheng, C.-F. You, and T.J. Wang (2013), Seasonal and spatial variability of the OM/OC mass ratios and high regional correlation between oxalic acid and zinc in Chinese urban organic aerosols, ''Atmos. Chem. Phys.'', 13, 4307-4318, doi:10.5194/acp-13-4307-2013. [https://atmoschem.org.cn/papers/Xing_et_al_2013_Atmospheric_Chemistry_and_Physics.pdf PDF]
#'''He, C.L.''', and '''T.-M. Fu*''' (2012), Air-sea exchange of volatile organic compounds: a new model with microlayer effects, ''Atmospheric and Oceanic Science Letters'', 6(2), 97-102. [https://atmoschem.org.cn/papers/He_et_al_2012_Atmospheric_and_Oceanic_Science_Letters.pdf PDF]
# '''Fu, T.-M.*''', J.J. Cao, X.Y. Zhang, S.C. Lee, Q. Zhang, Y.M. Han, W.J. Qu, Z. Han, R. Zhang, Y.X. Wang, D. Chen, and D.K. Henze (2012), Carbonaceous aerosols in China: top-down constraints on primary sources and estimation of secondary contribution, ''Atmos. Chem. Phys.'', 12, 2725-2746, doi:10.5194/acp-12-2725-2012. [https://atmoschem.org.cn/papers/Fu_et_al_2012_Atmospheric_Chemistry_and_Physics.pdf PDF]
# Heald, C.L.*, H. Coe, J.L. Jimenez, R.J. Weber, R. Bahreini, A.M. Middlebrook, L.M. Russell, M. Jolleys, '''T.-M. Fu''', J.D. Allan, K.N. Bower, G. Capes, J. Crosier, W.T. Morgan, N. H. Robinson, P.I. Williams, M.J. Cubison, P.F. DeCarlo, and E.J. Dunlea (2011), Exploring the vertical profile of atmospheric organic aerosol: comparing 17 aircraft field campaigns with a global model, ''Atmos. Chem. Phys.'', 11, 12673-12696, doi:10.5194/acpd-11-12673-2011. [https://atmoschem.org.cn/papers/Heald_et_al_2011_Atmospheric_Chemistry_and_Physics.pdf PDF]
# Pacifico, F.*, S.P. Harrison, C.D. Jones, A. Arneth, S. Sitch, G.P. Weedon, M.P. Barkley, P.I. Palmer, D. Seca, M. Potosnak, '''T.-M. Fu''', A. Goldstein, J. Bai, and G. Schurgers (2011), Evaluation of a photosynthesis-based biogenic isoprene emission scheme in JULES and simulation of isoprene emissions under present-day climate conditions, ''Atmos. Chem. Phys.'', 11, 4371-4389, doi:10.5194/acp-11-4371-2011.[https://atmoschem.org.cn/papers/Pacifico_et_al_2011_Atmospheric_Chemistry_and_Physics.pdf PDF]
# González Abad, G.*, N.D.C. Allen, P.F. Bernath, C.D. Boone, S.D. McLeod, G.L. Manney, G.C. Toon, C. Carouge, Y. Wang, S. Wu, M.P. Barkley, P.I. Palmer, Y. Xiao, and '''T.-M. Fu''' (2011), Ethane, ethyne and carbon monoxide concentrations in the upper troposphere and lower stratosphere from ACE and GEOS-Chem: a comparison study, ''Atmos. Chem. Phys.'', 11(18), 9927-9941, doi:10.5194/acp-11-9927-2011.[https://atmoschem.org.cn/papers/González_Abad_et_al_2011_Atmospheric_Chemistry_and_Physics.pdf PDF]
# Zhang, Y.W., Z.L. Gu*, S.C. Lee, '''T.-M. Fu''', and K.F. Ho (2011), Numerical simulation and in situ investigation of fine particle dispersion in an actual deep street canyon in Hong Kong, ''Indoor and Built Environ''., 20, 2, 206-216, doi:10.1177/1420326X10387694.[https://atmoschem.org.cn/papers/Zhang_et_al_2011_Indoor_and_Built_Environment.pdf PDF]
# '''Fu, T.-M.*''', D. J. Jacob, and C. L. Heald (2009), Aqueous-phase reactive uptake of dicarbonyls as a source of organic aerosol over eastern North America , ''Atmos. Environ.'', 43(10), 1814-1822, doi:10.1016/j.atmosenv.2008.12.029. [https://atmoschem.org.cn/papers/Fu_et_al_2009_Atmospheric_Chemistry_and_Physics.pdf PDF]
#Jacob, D.J., E.E. Drury, T.-M. Fu, E. Leibensperger, L. Mickley, A. Tai (2009), Aerosols over the United States: space observation, source characterization, and climate interactions, ''Geochimica et Cosmochimica Acta'', 73(13), A579-A579.[https://www.sciencedirect.com/science/article/pii/S0016703709002610 Link]
# Guo, H.*, A.J. Ding, T. Wang, I.J. Simpson, D.R. Blake, B. Barletta, S. Meinardi, '''T.-M. Fu''', Y.S. Li, and W.T. Hung (2009), Source origins, modeled profiles and apportionments of halogenated hydrocarbons in the greater Pearl River Delta region, southern China, ''J. Geophys. Res.'', doi:10.1029/2008JD011448.[https://atmoschem.org.cn/papers/Guo_et_al_2009_Atmospheric_Chemistry_and_Physics.pdf PDF]
# '''Fu, T.-M.*''', D. J. Jacob, F. Wittrock, J. P. Burrows, M. Vrekoussis, and D. K. Henze (2008), Global budgets of atmospheric glyoxal and methylglyoxal, and implications for formation of secondary organic aerosols, ''J. Geophys. Res.'', 113, D15303, doi:10.1026/2007JD009505. [https://atmoschem.org.cn/papers/Fu_et_al_2008_Journal_of_Geophysical_Research.pdf PDF]
# Henze, D. K.*, J. H. Seinfeld, N. L. Ng, J. H. Kroll, '''T.-M. Fu''', D. J. Jacob, and C. L. Heald (2008), Global modeling of secondary organic aerosol formation from aromatic hydrocarbons: high- vs. low-yield pathways, ''Atmos. Chem. Phys.'', 8, 2405-2401, doi:10.5194/acp-8-2405-2008. [https://atmoschem.org.cn/papers/Henze_et_al_2008_Atmospheric_Chemistry_and_Physics.pdf PDF]
# Liu, C.-M.*, M.-T. Yeh, S. Paul, Y.-C. Lee, D.J. Jacob, '''T.-M. Fu''', J.-H. Woo, G.R. Carmichael, and D.G. Streets (2008), Effect of anthropogenic emissions in East Asia on regional ozone levels during spring cold continental outbreaks near Taiwan: a case study, ''Environ. Model. Software'', 23(5), 579-591, doi:10.1016/j.envsoft.2007.08.007.[https://atmoschem.org.cn/papers/Liu_et_al_2008_Environmental_Modelling_and_Software.pdf PDF]
# Millet, D. B.*, D. J. Jacob, K. F. Boersma, '''T.-M. Fu''', T. P. Kurosu, K. Chance, C. L. Heald, and A. Guenther (2007), Spatial distribution of isoprene emissions from North America derived from formaldehyde column measurements by the OMI satellite sensor, ''J. Geophys. Res.'', 113, D02307, doi:10.1029/2007JD008950. [https://atmoschem.org.cn/papers/Millet_et_al_2007_Journal_of_Geophysical_Research.pdf PDF]
# '''Fu, T.-M.*''', D. J. Jacob, P. I. Palmer, K. Chance, Y. X. Wang, B. Barletta, D. R. Blake, J. C. Stanton, M. J. Pilling (2007), Space-based formaldehyde measurements as constraints on volatile organic compound emissions in East and South Asia, ''J. Geophys. Res.'', 112, D06312, doi:10.1029/2006JD007853. [https://atmoschem.org.cn/papers/Fu_et_al_2007_Journal_of_Geophysical_Research.pdf PDF]
# Wang, Y.X.*, M. B. McElroy, R. V. Martin, D. G. Streets, Q. Zhang, and '''T.-M. Fu''' (2007), Seasonal variability of NOx emissions over east China constrained by satellite observations: Implications for combustion and microbial sources, ''J. Geophys. Res.'', 112, D06301, doi:10.1029/2006JD007538. [https://atmoschem.org.cn/papers/Wang_et_al_2007_Journal_of_Geophysical_Research.pdf PDF]
# Sauvage, B.*, R. V. Martin, A. van Donkelaar, X. Liu, K. Chance, L. Jaegle, P. I. Palmer, S. Wu, and '''T.-M. Fu''' (2007), Remote sensed and in situ constraints on processes affecting tropical tropospheric ozone, ''Atmos. Chem. Phys.'', 7, 815-838, doi:10.5194/acp-7-815-2007. [https://atmoschem.org.cn/papers/Sauvage_et_al_2007_Atmospheric_Chemistry_and_Physics.pdf PDF]
# van Donkelaar, A.*, R. V. Martin, R. J. Park, C. L. Heald, '''T.-M. Fu''', H. Liao, and A. Guenther (2007), "Model evidence for a significant source of secondary organic aerosol from isoprene", ''Atmos. Environ.'', 41, 1267-1274. [https://atmoschem.org.cn/papers/van_Donkelaar_et_al_2007_Atmospheric_Environment.pdf PDF]
# Palmer, P. I.*, D. S. Abbot, '''T.-M. Fu''', D. J. Jacob, K. Chance, T. P. Kuruso, A. Guenther, C. Wiedinmyer, J. C. Stanton, M. J. Pilling, S. N. Pressley, B. Lamb, and A. L. Sumner (2006), Quantifying the seasonal and interannual variability of North American isoprene emissions using satellite observations of formaldehyde column, ''J. Geophys. Res.'', 111, D12315, doi:10.1029/2005JD006689. [https://atmoschem.org.cn/papers/Palmer_et_al_2006_Journal_of_Geophysical_Research.pdf PDF]
# Liu, X.*, K. Chance, C.E. Sioris, T.P. Kurosu, R,J.D. Spurr, R.V. Martin, '''T.-M. Fu''', J.A. Logan, D.J. Jacob, P.I. Palmer, M.J. Newchurch, I.A. Megretskaia, and R. Chatfield (2006), First directly-retrieved global distribution of tropospheric column ozone from GOME: comparison with the GEOS-CHEM model, ''J. Geophys. Res.'', 111, D02308. [https://atmoschem.org.cn/papers/Liu_et_al_2006_Journal_of_Geophysical_Research.pdf PDF]
# Jiang, X., Q. Xu, S. K. W. Dertinger, A. D. Stroock, '''T.-M. Fu''', and G. M. Whitesides *(2005), A general method for patterning gradients of biomolecules on surfaces using microfluidic networks, ''Analytical Chemistry'', 77(8), 2338 – 2347, doi:10.1021/ac048440m.[https://atmoschem.org.cn/papers/Jiang_et_al_2005_Analytical_Chemistry.pdf PDF]
# '''Fu, T.-M.''', and J. P. Chen (2001), The intricate beauty of bubbles. National Science Council Monthly, 29(11), 788-796. (In Chinese)[https://atmoschem.org.cn/papers/Fu_et_al_2001_National_Science_Council_Monthly.pdf PDF]

Publications

2023-10-26T03:10:49Z

Atomoschem: /* Published / In press */

=Published / In press=
#'''Feng, X.''', '''Ma, Y.''', '''Lin, H.''', '''Fu, T.-M.*''', Zhang, Y., '''Wang, X.''', '''Zhang, A.''', Yuan, Y., Han, Z., Mao, J., Wang, D., Zhu, L., '''Wu, Y.''', Li, Y., Yang, X. (2023), Impacts of ship emissions on air quality in Southern China: opportunistic insights from the abrupt emission changes in early 2020, ''Environmental Science & Technology'', doi:10.1021/acs.est.3c04155. [https://atmoschem.org.cn/papers/1Feng_et_al_2023-Impacts-of-ship-emissions-on-air-quality-in-southern-china-opportunistic-insights-from-the-abrupt.pdf PDF] [https://pubs.acs.org/doi/epdf/10.1021/acs.est.3c04155 Full text].
#'''Li, Y.''', '''Fu, T.-M.*''', Yu, J. Z.*, Yu, X., Chen, Q., Miao, R., Zhou, Y., '''Zhang, A.''', Ye, J., Yang, X., Tao, S., Liu, H., Yao, W. (2023), Dissecting the contributions of organic nitrogen aerosols to global atmospheric nitrogen deposition and implications for ecosystems, ''National Science Review'', nwad244, doi:10.1093/nsr/nwad244. [https://atmoschem.org.cn/papers/2Li_et_al_2023_National_Science_Review_Dissecting.pdf PDF] [https://doi.org/10.1093/nsr/nwad244 Full text]
# Zhai, J., Yu, G., Zhang, J., Shi, S., Yuan, Y., Jiang, S., Xing, C., Cai, B., Zeng, Y., Wang, Y., Zhang, A., Zhang, Y., '''Fu, T.-M.''', Zhu, L., Shen, H., Ye, J., Wang, C., Tao, S., Li, M., Zhang, Y.*, Yang, X.* (2023), Impact of ship emissions on air quality in the Greater Bay Area in China under the Latest Global Marine Fuel Regulation, ''Enviornmental Science & Technology'', doi:10.1021/acs.est.3c03950. [https://atmoschem.org.cn/papers/3Zhai_et_al_2023_EST_Impact-of-ship-emissions.pdf PDF] [https://pubs.acs.org/doi/10.1021/acs.est.3c03950 Full text].
# 刘婵芳, '''张傲星*''', 房庆, 叶毓婧, 杨红龙, '''陈炯恺''', '''吴雯潞''', '''侯岳''', '''莫佳佳''', '''傅宗玫'''. (2023), 深圳市2022年春季新冠疫情管控期间空气质量分析[J/OL], ''环境科学'', 44(6):3117-3129, doi:10.13227/j.hjkx.202205313. [https://atmoschem.org.cn/papers/4Shenzhen_2022_Covid_HuanJingKeXue.pdf PDF] [https://www.hjkx.ac.cn/hjkx/ch/reader/view_abstract.aspx?flag=1&file_no=20230612&journal_id=hjkx Full text]
# '''Zhang, A.''', '''Fu, T.-M.*''', '''Feng, X.''', Guo, J., Liu, C., '''Chen, J.''', '''Mo, J.''', Zhang, X., '''Wang, X.''', '''Wu, W.''', '''Hou, Y.''', Yang, H., Lu, C. (2023), Deep learning-based ensemble forecasts and predictability assessments for surface ozone pollution. ''Geophysical Research Letters'', e2022GL102611, doi:10.1029/2022GL102611. [https://atmoschem.org.cn/papers/5GRL_2023_Zhang_Deep_Learning_Forecasts.pdf PDF] [https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2022GL102611 Full text]
# '''Wang, X.''', '''Fu, T.-M.*''', Zhang, L.*, Lu, X., Liu, X., Amnuaylojaroen, T., Latif, M. T., '''Ma, Y.''', '''Zhang, L.''', '''Feng, X.''', Zhu, L., Shen, H., Yang, X. (2022), Rapidly changing emissions drove substantial surface and tropospheric ozone increases over Southeast Asia, ''Geophysical Research Letters'', e2022GL100223, doi:10.1029/2022GL100223. [https://atmoschem.org.cn/papers/Wang_et_al_2022_Geophysical_Research_Letters.pdf PDF] [https://agupubs.onlinelibrary.wiley.com/doi/epdf/10.1029/2022GL100223 Full text].
# Xing, C., Wang, Y., Yang, X., Zeng, Y., Zhai, J., Cai, B., Zhang, A., '''Fu, T.-M.''', Zhu, L., Li, Y., Wang, X., Zhang, Y. (2022), Seasonal variation of driving factors of ambient PM2.5 oxidative potential in Shenzhen, China, ''Science of the Total Environment'', 862(1), doi:10.1016/j.scitotenv.2022.160771.[https://atmoschem.org.cn/papers/Xing_et_al_2022_Science_of_the_Total_Environment.pdf PDF] [https://www.sciencedirect.com/science/article/pii/S0048969722078743 Full text].
# Zhai, J., Yang, X., Li, L., Ye, X., Chen, J., '''Fu, T.-M.''', Zhu, L., Shen, H., Ye, J., Wang, C., Tao S. (2022). Direct observation of the transitional stage of mixing-state-related absorption enhancement for atmospheric black carbon. ''Geophysical Research Letters'', 49, e2022GL101368, doi:10.1029/2022GL101368. [https://atmoschem.org.cn/papers/Zhai_et_al_2022_Geophysical_Research_Lett.pdf PDF] [https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2022GL101368 Full text].
# Pu, D., Zhu, L., De Smedt, I., Li, X., Sun, W., Wang, D., Liu, S., Li, J., Shu, L., Chen, Y., Sun, S., Zuo, X., Fu, W., Xu, P., Yang, X., '''Fu, T.-M.''' (2022), Response of anthropogenic volatile organic compound emissions to urbanization in Asia probed with TROPOMI and VIIRS satellite observations, ''Geophysical Research Letters'', e2022GL099470, doi:10.1029/2022GL099470. [https://atmoschem.org.cn/papers/Pu_et_al_2022_Geophysical_Research_Letters.pdf PDF ] [https://agupubs.onlinelibrary.wiley.com/doi/10.1029/2022GL099470 Full text].
# '''Long, X.''', '''Fu, T.-M.*''', Yang, X., Tang, Y., Zheng, Y., Zhu, L., Shen, H., Ye, J., Wang, C., Wang, T., Li, B. (2022), Efficient atmospheric transport of microplastics over Asia and adjacent oceans, ''Enviornmental Science & Technology'', 56(10), 6243–6252, doi:10.1021/acs.est.1c07825.[https://atmoschem.org.cn/papers/Long_et_al_2022_Environmental_Science_and_Technology.pdf PDF ] [https://pubs.acs.org/doi/10.1021/acs.est.1c07825 Full text].
#Shu, L., Zhu, L., Bak, J., Zoogman, P., Han, H., Long, X., Bai, B., Liu, S., Wang, D., Sun, W., Pu, D., Chen, Y., Li, X., Sun, S., Li, J., Yang, X., '''Fu, T.-M.''' (2022), Improved Ozone Simulation in East Asia via Assimilating Observations from the First Geostationary Air-quality Monitoring Satellite: Insights from an Observing System Simulation Experiment, ''Atmospheric Environment'', 274, 119003, doi:10.1016/j.atmosenv.2022.119003. [https://atmoschem.org.cn/papers/Shu_et_al_2022_Atmospheric_Environment.pdf PDF ] [https://www.sciencedirect.com/science/article/pii/S1352231022000681?via%3Dihub Full text].
# Xu, X., '''Feng, X.''', '''Lin, H.''', Zhang, P., Huang, S., Song, Z., Peng, Y., '''Fu, T.-M.''', Zhang, Y. (2022), Modeling the high-mercury wet deposition in the southeastern US with WRF-GC-Hg v1.0, ''Geoscientific Model Development'', 15, 3845–3859, doi:10.5194/gmd-15-3845-2022.[https://atmoschem.org.cn/papers/Xu_et_al_2022_Geoscientific_Model_Development.pdf PDF ] [https://gmd.copernicus.org/articles/15/3845/2022/ Full text].
# Zhai, J., Yang, X., Li, L., Bai, B., Liu, P., Huang, Y., '''Fu, T.-M.''', Zhu, L., Zeng, Z., Tao, S., Lu, X., Ye, X., Wang, X., Wang, L., Chen, J. (2022), Absorption enhancement of black carbon aerosols constrained by mixing-state heterogeneity, ''Environmental Science & Technology'', 56(3), 1586–1593, doi:10.1021/acs.est.1c06180. [https://atmoschem.org.cn/papers/Zhai_et_al_2022_Environmental_Science_and_Technology.pdf PDF ] [https://pubs.acs.org/doi/10.1021/acs.est.1c06180 Full text]
# Xing, L., '''Fu, T.-M.''', Liu, T., Qin, Y., Zhou, L., Chan, C. K., Guo, H., Yao, D., Duan, K. (2022), Estimating organic aerosol emissions from cooking in winter over the Pearl River Delta region, China, ''Environmental Pollution'', 292(A), 118266, doi:10.1016/j.envpol.2021.118266. [https://atmoschem.org.cn/papers/Xing_et_al_2021_Environmental_Pollution.pdf PDF ] [https://www.sciencedirect.com/science/article/pii/S0269749121018480 Full text]
# Cao, H., Henze, D. K., Cady-Pereira, K., McDonald, B. C., Harkins, C., Sun, K., Bowman, K. W., '''Fu, T.-M.''', Nawaz, M. O. (2021), COVID-19 lockdowns afford the first satellite-based confirmation that vehicles are an under-recognized source of urban NH3 pollution in Los Angeles, ''Environmental Science & Technology Letters'', 9(1), 3-9, doi:10.1021/acs.estlett.1c00730. [https://atmoschem.org.cn/papers/Cao_et_al_2021_Environmental_Science_and_Technology_Letters.pdf PDF ] [https://pubs.acs.org/doi/10.1021/acs.estlett.1c00730 Full text]
# '''Feng, X.''', '''Lin, H.''', '''Fu, T.-M.*''', Sulprizio, M. P., Zhuang, J., Jacob, D. J., '''Tian, H.''', '''Ma, Y.''', '''Zhang, L.''', '''Wang, X.''', Chen, Q., Han, Z. (2021), WRF-GC (v2.0): online two-way coupling of WRF (v3.9.1.1) and GEOS-Chem (v12.7.2) for modeling regional atmospheric chemistry-meteorology interactions, ''Geosci. Model. Dev.'', 14，3741-3768，doi:10.5194/gmd-14-3741-2021. [https://atmoschem.org.cn/papers/Feng_et_al_2021_Geoscientific_Model_Development.pdf PDF ] [https://gmd.copernicus.org/articles/14/3741/2021/ Full text]
# '''Wang, X.''', '''Fu, T.-M.*''', Zhang, L.*, '''Cao, H.''', Zhang, Q. Ma, H., Shen, L., Evans, M., Ivatt, P., Lu., X., Chen, Y., '''Zhang, L.''', '''Feng, X.''', Yang, X., Zhu, L., Henze, D. (2021), Sensitivities of ozone air pollution in the Beijing-Tianjin-Hebei area to local and upwind precursor emissions using adjoint modelling, ''Environmental Science & Technology'', 55(9),5752-5762, doi:10.1021/acs.est.1c00131. [https://atmoschem.org.cn/papers/Wang_et_al_2021_Environmental_Science_and_Technology.pdf PDF ] [https://doi.org/10.1021/acs.est.1c00131 Full text].
# '''Li, Y.''', '''Fu, T.-M.*''', Yu, J. Z.*, '''Feng, X.''', '''Zhang, L.''', Chen, J., Boreddy, S. K. R., Kawamura, K., Fu, P., Yang, X., Zhu, L., Zeng, Z. (2021), Impacts of chemical degradation on the global budget of atmospheric levoglucosan and its use as a biomass burning tracer, ''Environmental Science & Technology'', 55(8), 5525-5536, doi:10.1021/acs.est.0c07313. [https://atmoschem.org.cn/papers/li_et_al_2021_Environmental_Science_and_Technology.pdf PDF ] [https://doi.org/10.1021/acs.est.0c07313 Full text].
# Zhang, R., Gen, M. '''Fu, T.-M.''', Chan, C. (2021), Production of formate via oxidation of glyoxal promoted by particulate nitrate photolysis, ''Environmental Science & Technology'', 55(9), 5711-5720, doi:10.1021/acs.est.0c081999. [https://atmoschem.org.cn/papers/Zhang_et_al_2021_Environmental_Science_and_Technology.pdf PDF ] [https://doi.org/10.1021/acs.est.0c08199 Full text]
# Hu, S., Wang, D., Wu, J., Zhou, L., '''Feng, X.''', '''Fu, T.-M.''', Yang, X., Ziegler, A. D., Zeng, Z. (2021), Aerosol presence reduces the diurnal temperature range: an interval when the COVID-19 pandemic reduced aerosols revealing the effect on climate, ''Environmental Science: Atmospheres'', doi:10.1039/D1EA00021G. [https://atmoschem.org.cn/papers/Hu_et_al_2021_Environmental_Science_Atmospheres.pdf PDF ] [https://pubs.rsc.org/vi/content/articlelanding/2021/ea/d1ea00021g#! Full text]
# Sun, W., Zhu, L., De Smedt, I., Bai, B., Pu, D., Chen, Y., Shu, L., Wang, D., '''Fu, T.-M.''', Wang, X., and Yang, X. (2021): Global Significant Changes in Formaldehyde (HCHO) Columns Observed from Space at the Early Stage of the COVID-19 Pandemic, ''Geophys. Res. Lett'', doi:10.1029/2020GL091265. [https://atmoschem.org.cn/papers/Sun_et_al_2021_Geophys_Res_Lett.pdf PDF ] [https://doi.org/10.1029/2020GL091265 Full text]
# Fan, W., Liu, Y., Chappell, A. Dong, L., Xu, R. Ekstrom, M., '''Fu., T.-M.''', Zeng Z. (2021), Evaluation of global reanalysis land surface wind speed trends to support wind energy development using in situ observations, ''J. Applied Meteorology and Climatology'', 60(1), 33-50, doi:10.1175/JAMC-D-20-0037.1. [https://atmoschem.org.cn/papers/Fan_et_al_2021_J_Applied_Meteorology_and_Climatology.pdf PDF ] [https://journals.ametsoc.org/view/journals/apme/60/1/jamc-d-20-0037.1.xml Full text]
# '''Lin, H.''', '''Feng, X.''', '''Fu, T.-M.*''', '''Tian, H.''', '''Ma, Y.''', '''Zhang, L.''', Jacob, D.J., Yantosca, R.M., Sulprizio, M.P., Lundgren, E.W., Zhuang, J., Zhang, Q., Lu, X., Zhang, L., Shen, L., Guo, J., Eastham, S.D., Keller, C.A. (2020), WRF-GC (v1.0): online coupling of WRF (v3.9.1.1) and GEOS-Chem (v12.2.1) for regional atmospheric chemistry modeling – Part 1: Description of the one-way model, ''Geosci. Model Dev.'', doi:10.5194/gmd-13-3241-2020. [https://atmoschem.org.cn/papers/Lin_et_al_2020_Geoscientific_Model_Development.pdf PDF ] [https://gmd.copernicus.org/articles/13/3241/2020/gmd-13-3241-2020.html Full text]
# Elguindi, N., Granier, C., Stavrakou, S., Darras, S., Bauwens, M., '''Cao, H.''', Chen, C., Denier van der Gon, H. A. C., Dubovik, O., '''Fu, T.-M.''', Henze, D. K., Jiang, Z., Keita, S., Kuenen, J. J. P., Kurokawa, J., Liousse, C., Miyazaki, K., Muller, J.-F., Qu, Z., Solmon, F., Zheng, B. (2020), Intercomparison of magnitudes and trends in anthropogenic surface emissions from bottom-up inventories, top-down estimates, and emission scenarios. ''Earth's Future'',doi：10.1029/2020EF001520[https://atmoschem.org.cn/papers/N.Elguindi_et_al_Earth's_Future.pdf PDF ] [https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2020EF001520 Full text]
# '''Ma, Y.''', '''Fu, T.-M.*''', '''Tian, H.''', Gao, J., Hu, M., Guo, J., Zhang, Y., Sun, Y., '''Zhang, L.''', Yang, X., Wang, X. (2020), Emergency Response Measures to Alleviate a Severe Haze Pollution Event in Northern China during December 2015: Assessment of Effectiveness. ''Aerosol and Air Quality Research'', doi:10.4209/aaqr.2019.09.0442. [https://atmoschem.org.cn/papers/Ma_et_al_2020_Aerosol_and_Air_Quality_Research.pdf PDF] [https://aaqr.org/articles/aaqr-19-09-oa-0442 Full Text]
# Wang, X., Ye, X., Chen, J., Wang, X., Yang, X., '''Fu, T.-M.''', Zhu, L., Liu, C. (2020), Direct links between hygroscopicity and mixing state of ambient aerosols: estimating particle hygroscopicity from their single-particle mass spectra, ''Atmos. Chem. Phys.'', 20, 6273–6290, doi:10.5194/acp-20-6273-2020. [https://atmoschem.org.cn/papers/Wang_et_al_2020_Atmospheric_Chemistry_and_Physics.pdf PDF] [https://acp.copernicus.org/articles/20/6273/2020/ Full Text]
#Xu, X., Lu, X., Li, X. Liu, Y., Wang, X., Chen, H., Chen, J., Yang, X., '''Fu, T.-M.''', Zhao, Q., Fu, Q. (2020), ROS-generation potential of Humic-like substances (HULIS) in ambient PM2.5 in urban Shanghai: Association with HULIS concentration and light absorbance, ''Chemosphere'', 256, 127050, doi: 10.1016/j.chemosphere.2020.127050. [https://atmoschem.org.cn/papers/Xu-et-al-2020-Chemosphere.pdf PDF ][https://www.sciencedirect.com/science/article/pii/S0045653520312431 Full Text]
# Zhang, R., Zhang, Y., '''Lin, H.''', '''Feng, X.''', '''Fu, T.-M.''', Wang, Y. (2020), NOx emission reduction and recovery during COVID-19 in East China, ''Atmosphere'', 11(4), 433, doi:10.3390/atmos11040433. [https://atmoschem.org.cn/papers/Zhang-et-al-2020-Atmosphere.pdf PDF ] [https://www.mdpi.com/2073-4433/11/4/433 Full Text]
# '''Jiang, Z.''', Jolleys, M. D., '''Fu, T.-M.*''', Palmer, P. I.*, '''Ma, Y.''', '''Tian, H.''', Li, J., Yang, X. (2020), Spatiotemporal and probability variations of surface PM2.5 over China between 2013 and 2019 and the associated changes in health risks: an integrative observation and model analyses, ''Science of the Total Environment'', 723, doi:10.1016/j.scitotenv.2020.137896. [https://atmoschem.org.cn/papers/Jiang-et-al-2020-Science-of-the-Total-Environment.pdf PDF ]
[https://www.sciencedirect.com/science/article/pii/S0048969720314091 Full Text]
# '''Zhang, L.''', '''Fu, T.-M.*''', '''Tian, H.''', '''Ma, Y.''', Chen, J.-P., Tsai, T.-C., Tsai, I.-C., Meng, Z., Yang, X. (2020), Anthropogenic aerosols significantly reduce mesoscale convective system occurrences and precipitation over Southern China in April, ''Geophys. Res. Lett.'', doi: 10.1029/2019GL086204. [https://atmoschem.org.cn/papers/Zhang-et-al-2020-Geophys.-Res.-Lett.pdf PDF ]
[https://agupubs.onlinelibrary.wiley.com/doi/10.1029/2019GL086204 Full Text]
# Zhang*, Y., Vu, T. V., Sun, J., He, J., Shen, X., Lin, W., Zhang, X., Zhong, J., Gao, W., Wang, Y., '''Fu, T.-M.''', '''Ma., Y.''', Li, W., Shi, Z. (2020), Significant Changes in Chemistry of Fine Particles in Wintertime Beijing from 2007 to 2017: Impact of Clean Air Actions, ''Environmental Science & Technology'', doi:10.1021/acs.est.9b04678. [https://atmoschem.org.cn/papers/Zhang-et-al-2020-Environmental-Science-Technology.pdf PDF ] [https://pubmed.ncbi.nlm.nih.gov/31766848/ Full Text]
# Zhao, Y.-H., Zhang, L.*, Zhou, M., Chen, D., Lu, X., Tao, W., Liu, J.-F., '''Tian, H.''', '''Ma, Y.-P.''', '''Fu, T.-M.'''(2019), Influences of planetary boundary layer mixing parameterization on summertime surface ozone concentration and dry deposition over North China, ''Atmospheric Environment'', 218, 116950, doi:10.1016/j.atmosenv.2019.116950. [https://atmoschem.org.cn/papers/Zhao_et_al_2019_Atmospheric_Environment.pdf PDF ] [https://www.sciencedirect.com/science/article/pii/S1352231019305898 Full Text]
# Lu, X.*, Zhang, L.*, Chen, Y., Zhou, M., Zheng, B., Li, K., Liu, Y., Lin, J., '''Fu, T.-M.''', and Zhang, Q. (2019), Exploring 2016–2017 surface ozone pollution over China: source contributions and meteorological influences, ''Atmos. Chem. Phys.'', 19, 8339–8361, doi:10.5194/acp-19-8339-2019. [https://atmoschem.org.cn/papers/Lu_et_al_2019_Atmospheric_Chemistry_and_Physics.pdf PDF ] [https://acp.copernicus.org/articles/19/8339/2019/ Full Text]
# '''Fu, T.-M.*''' and '''H. Tian''' (2019), Climate change penalty to ozone air quality: review of current understandings and knowledge gaps, ''Current Pollution Reports'', 5, 159–171, doi:10.1007/s40726-019-00115-6. [https://atmoschem.org.cn/papers/Fu_et_al_2019_Current_Pollution_Reports.pdf PDF ] [https://link.springer.com/article/10.1007/s40726-019-00115-6 Full Text]
# Shen, L.*, D. J. Jacob, L. Zhu, Q. Zhang, B. Zheng, M. P. Sulprizio, K. Li, I. De Smedt, G. González Abad, '''H. Cao''', '''T.-M. Fu''', and H. Liao (2019), The 2005–2016 trends of formaldehyde columns over China observed by satellites: Increasing anthropogenic emissions of volatile organic compounds and decreasing agricultural fire emissions, ''Geophysical Research Letters'', 46. doi:10.1029/2019GL082172 [https://atmoschem.org.cn/papers/Shen_et_al_2019_Geophysical_Research_Lett.pdf PDF ] [https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2019GL082172 Full Text]
# '''Feng, X.''', '''T.-M. Fu*''', '''H. Cao''', '''H. Tian''', Q. Fan, X. Chen (2019), Neural network prediction of pollutant emissions from open burning of crop residues: application to air quality forecasts in Southern China, ''Atmospheric Environment'', 204, 22-31, doi:10.1016/j.atmosenv.2019.02.002 [https://atmoschem.org.cn/papers/Feng_et_al_2019_Atmospheric_Environment.pdf PDF ] [https://www.sciencedirect.com/science/article/pii/S135223101930086X Full Text]
# Zhou, M., L. Zhang*, D. Chen*, Y. Gu, '''T.-M. Fu''', M. Gao, Y. Zhao, X. Lu, and B. Zhao (2018), The impact of aerosol-radiation interactions on the effectiveness of emission control measures, ''Environmental Research Letters'', 14(2), 024002, doi:10.1088/1748-9326/aaf27d [https://atmoschem.org.cn/papers/Zhou_et_al_2018_Environmental_Research_Letters.pdf Full text]
# '''Cao, H.''', '''T.-M. Fu*''', L. Zhang, D. K. Henze, C. Chan Miller, C. Lerot, G. Gonzalex Abad, I. De Smedt, Q. Zhang, M. van Roosendael, K. Chance, J. Li, J. Zheng, and Y. Zhao (2018), Adjoint inversion of Chinese non-methane volatile organic compound emissions using space-based observations of formaldehyde and glyoxal, ''Atmospheric Chemistry and Physics'', 18, 15017-15046, doi:10.5194/acp-18-15017-2018. [https://atmoschem.org.cn/papers/Cao_et_al_2018_Atmospheric_Chemistry_and_Physics.pdf Full text]
# '''Xing, L.''', M. Shrivastava*, '''T.-M. Fu*''', P. Roldin, Y. Qian, L. Xu, N. L. Ng, J. Shilling, A. Zelenyuk, and C. Cappa (2018), Parameterized yields of semi-volatile products from isoprene oxidation under different NOx levels:impacts of chemical aging and wall-loss of reactive gases, ''Environmental Science and Technology'', doi: 10.1021/acs.est.8b00373. [https://atmoschem.org.cn/papers/Xing_et_al_2018_Environmental_Science_and_Technology.pdf Full text] [https://pubs.acs.org/doi/suppl/10.1021/acs.est.8b00373/suppl_file/es8b00373_si_001.pdf SI]
# Liu, M.-Y., Lin, J.-T.*, Wang, Y.-C., Sun, Y., Zheng, B., Shao, J., Chen, L.-L., Zheng, Y., Chen, J., Fu, T.-M., Yan, Y.-Y., Zhang, Q., and Wu, Z. (2018),Spatiotemporal variability of NO2 and PM2.5 over Eastern China: observational and model analyses with a novel statistical method, ''Atmospheric Chemistry and Physics'', 18, 12933-12952, doi:10.5194/acp-18-12933-2018.[https://atmoschem.org.cn/papers/Liu_et_al_2018_Atmospheric_Chemistry_and_Physics.pdf Full text]
# Chen, Q.*, '''T.-M. Fu*''', J. Hu*, Q. Ying, and L. Zhang (2017), Modelling secondary organic aerosols in China, ''National Science Review'', 4(6), 806-809, doi:10.1093/nsr/nwx143. [https://atmoschem.org.cn/papers/Chen_et_al_2017_National_Science_Review.pdf Full text]
# Li, N., J.-P. Chen*, I.-C. Tsai, Q. He, S.-Y. Chi, Y.-C. Lin, and '''T.-M. Fu''' (2016), Potential impacts of electric vehicles on air quality in Taiwan, ''Science of the Total Environment'', 566-567, 919-928, doi:10.1016/j.scitotenv.2016.05.105.[https://atmoschem.org.cn/papers/Li_et_al_2016_Science_of_the_Total_Environment.pdf Full text]
# '''Xu, W.''', '''T.-M. Fu*''', '''J. Chen''', and '''H. Tian''' (2016), Ground-based measurement and variation analysis of carbonaceous aerosols in Wuqing, ''Acta Scientiarum Naturalium Universitatis Pekinensis'', 52(3), 409-419, doi:10.13209/j.0479-8023.2015.144. (In Chinese)[https://atmoschem.org.cn/papers/Xu_et_al_2016_Acta_Scientiarum_Naturalium_Universitatis_Pekinensis.pdf Full text]
# Tsai, I.C., J.-P. Chen*, C. S.-C. Lung, '''N. Li''', W.-N. Chen, '''T.-M. Fu''', C.-C. Chang, and G.-D. Hwang (2015), Sources and formation pathways of organic aerosol in a subtropical metropolis during summer, ''Atmospheric Environment'', 117, 51-60, doi:10.1016/j.atmosenv.2015.07.005. [https://atmoschem.org.cn/papers/Tsai_et_al_2015_Atmospheric_Environment.pdf Full text]
# '''Fu, T.-M.*''', '''Y. Zheng''', F. Paulot, J. Mao, and R. M. Yantosca (2015), Positive but variable sensitivity of August surface ozone to large-scale warming in the southeast United States, ''Nature Climate Change'', 5, 454-458, doi:10.1038/nclimate2567. [https://atmoschem.org.cn/papers/Fu_et_al_2015_Nature_Climate_Change.pdf Full text]
# Zhang, L.*, L. Liu, Y. Zhao, S. Gong, X. Zhang, D. K. Henze, S. L. Capps, '''T.-M. Fu''', and Q. Zhang (2015), Source Attribution of Particulate Matter Pollution over North China with the Adjoint Method, ''Environmental Research Letters'', 10, 084011, doi:10.1088/1748-9326/10/8/084011.[https://atmoschem.org.cn/papers/Zhang_et_al_2015_Environmental_Research_Letters.pdf Full text]
# '''Xing, L.''', and '''T.-M. Fu*''' (2015), Contributions of organic aerosols to cloud condensation nuclei numbers in China, ''Acta Scientiarum Naturalium Universitatis Pekinensis'', 51(1), 13-23, doi:10.13209/j.0479-8023.2014.143. (In Chinese) [https://atmoschem.org.cn/papers/Xing_et_al_2015_Acta_Scientiarum_Naturalium_Universitatis_Pekinensis.pdf Full text]
# '''Jian, Y.''', and '''T.-M. Fu*''' (2014), Injection heights of springtime biomass burning plumes over the Peninsular Southeast Asia and their impacts on pollutant long-range transport, ''Atmos. Chem. Phys.'', 14, 3977-3989, doi:10.5194/acp-14-3977-2014. [https://atmoschem.org.cn/papers/Jian_et_al_2014_Atmospheric_Chemistry_and_Physics.pdf Full text]
# Zhang, Y., L. Qiao, '''Y. Ren''', X. Wang, M. Gao, Y. Tang, J. J. Xi, '''T.-M. Fu*''', and X. Jiang* (2013), Two dimensional barcode-inspired automatic analysis for arrayed microfluidic immunoassays, ''Biomicrofluidics'', 7, 034110, doi:10.1063/1.4811278. [https://atmoschem.org.cn/papers/Zhang_et_al_2013_Biomicrofluidics.pdf PDF]
# '''Li, N'''., '''T.-M. Fu*''', J.J. Cao*, S.C. Lee, X.-F. Huang, L.-Y. He, K.-F. Ho, J. S. Fu, and Y.-F. Lam (2013), Sources of secondary organic aerosols in the Pearl River Delta region in fall: contributions from the aqueous reactive uptake of dicarbonyls, ''Atmos. Environ.'', 76, 200-207, doi:10.1016/j.atmosenv.2012.12.005. [https://atmoschem.org.cn/papers/Li_et_al_2013_Atmospheric_Environment.pdf PDF]
# '''Xing, L.''', '''T.-M. Fu*''', J.J. Cao, S.C. Lee, G.H. Wang, K.-F. Ho, M.-C. Cheng, C.-F. You, and T.J. Wang (2013), Seasonal and spatial variability of the OM/OC mass ratios and high regional correlation between oxalic acid and zinc in Chinese urban organic aerosols, ''Atmos. Chem. Phys.'', 13, 4307-4318, doi:10.5194/acp-13-4307-2013. [https://atmoschem.org.cn/papers/Xing_et_al_2013_Atmospheric_Chemistry_and_Physics.pdf PDF]
#'''He, C.L.''', and '''T.-M. Fu*''' (2012), Air-sea exchange of volatile organic compounds: a new model with microlayer effects, ''Atmospheric and Oceanic Science Letters'', 6(2), 97-102. [https://atmoschem.org.cn/papers/He_et_al_2012_Atmospheric_and_Oceanic_Science_Letters.pdf PDF]
# '''Fu, T.-M.*''', J.J. Cao, X.Y. Zhang, S.C. Lee, Q. Zhang, Y.M. Han, W.J. Qu, Z. Han, R. Zhang, Y.X. Wang, D. Chen, and D.K. Henze (2012), Carbonaceous aerosols in China: top-down constraints on primary sources and estimation of secondary contribution, ''Atmos. Chem. Phys.'', 12, 2725-2746, doi:10.5194/acp-12-2725-2012. [https://atmoschem.org.cn/papers/Fu_et_al_2012_Atmospheric_Chemistry_and_Physics.pdf PDF]
# Heald, C.L.*, H. Coe, J.L. Jimenez, R.J. Weber, R. Bahreini, A.M. Middlebrook, L.M. Russell, M. Jolleys, '''T.-M. Fu''', J.D. Allan, K.N. Bower, G. Capes, J. Crosier, W.T. Morgan, N. H. Robinson, P.I. Williams, M.J. Cubison, P.F. DeCarlo, and E.J. Dunlea (2011), Exploring the vertical profile of atmospheric organic aerosol: comparing 17 aircraft field campaigns with a global model, ''Atmos. Chem. Phys.'', 11, 12673-12696, doi:10.5194/acpd-11-12673-2011. [https://atmoschem.org.cn/papers/Heald_et_al_2011_Atmospheric_Chemistry_and_Physics.pdf PDF]
# Pacifico, F.*, S.P. Harrison, C.D. Jones, A. Arneth, S. Sitch, G.P. Weedon, M.P. Barkley, P.I. Palmer, D. Seca, M. Potosnak, '''T.-M. Fu''', A. Goldstein, J. Bai, and G. Schurgers (2011), Evaluation of a photosynthesis-based biogenic isoprene emission scheme in JULES and simulation of isoprene emissions under present-day climate conditions, ''Atmos. Chem. Phys.'', 11, 4371-4389, doi:10.5194/acp-11-4371-2011.[https://atmoschem.org.cn/papers/Pacifico_et_al_2011_Atmospheric_Chemistry_and_Physics.pdf PDF]
# González Abad, G.*, N.D.C. Allen, P.F. Bernath, C.D. Boone, S.D. McLeod, G.L. Manney, G.C. Toon, C. Carouge, Y. Wang, S. Wu, M.P. Barkley, P.I. Palmer, Y. Xiao, and '''T.-M. Fu''' (2011), Ethane, ethyne and carbon monoxide concentrations in the upper troposphere and lower stratosphere from ACE and GEOS-Chem: a comparison study, ''Atmos. Chem. Phys.'', 11(18), 9927-9941, doi:10.5194/acp-11-9927-2011.[https://atmoschem.org.cn/papers/González_Abad_et_al_2011_Atmospheric_Chemistry_and_Physics.pdf PDF]
# Zhang, Y.W., Z.L. Gu*, S.C. Lee, '''T.-M. Fu''', and K.F. Ho (2011), Numerical simulation and in situ investigation of fine particle dispersion in an actual deep street canyon in Hong Kong, ''Indoor and Built Environ''., 20, 2, 206-216, doi:10.1177/1420326X10387694.[https://atmoschem.org.cn/papers/Zhang_et_al_2011_Indoor_and_Built_Environment.pdf PDF]
# '''Fu, T.-M.*''', D. J. Jacob, and C. L. Heald (2009), Aqueous-phase reactive uptake of dicarbonyls as a source of organic aerosol over eastern North America , ''Atmos. Environ.'', 43(10), 1814-1822, doi:10.1016/j.atmosenv.2008.12.029. [https://atmoschem.org.cn/papers/Fu_et_al_2009_Atmospheric_Chemistry_and_Physics.pdf PDF]
#Jacob, D.J., E.E. Drury, T.-M. Fu, E. Leibensperger, L. Mickley, A. Tai (2009), Aerosols over the United States: space observation, source characterization, and climate interactions, ''Geochimica et Cosmochimica Acta'', 73(13), A579-A579.[https://www.sciencedirect.com/science/article/pii/S0016703709002610 Link]
# Guo, H.*, A.J. Ding, T. Wang, I.J. Simpson, D.R. Blake, B. Barletta, S. Meinardi, '''T.-M. Fu''', Y.S. Li, and W.T. Hung (2009), Source origins, modeled profiles and apportionments of halogenated hydrocarbons in the greater Pearl River Delta region, southern China, ''J. Geophys. Res.'', doi:10.1029/2008JD011448.[https://atmoschem.org.cn/papers/Guo_et_al_2009_Atmospheric_Chemistry_and_Physics.pdf PDF]
# '''Fu, T.-M.*''', D. J. Jacob, F. Wittrock, J. P. Burrows, M. Vrekoussis, and D. K. Henze (2008), Global budgets of atmospheric glyoxal and methylglyoxal, and implications for formation of secondary organic aerosols, ''J. Geophys. Res.'', 113, D15303, doi:10.1026/2007JD009505. [https://atmoschem.org.cn/papers/Fu_et_al_2008_Journal_of_Geophysical_Research.pdf PDF]
# Henze, D. K.*, J. H. Seinfeld, N. L. Ng, J. H. Kroll, '''T.-M. Fu''', D. J. Jacob, and C. L. Heald (2008), Global modeling of secondary organic aerosol formation from aromatic hydrocarbons: high- vs. low-yield pathways, ''Atmos. Chem. Phys.'', 8, 2405-2401, doi:10.5194/acp-8-2405-2008. [https://atmoschem.org.cn/papers/Henze_et_al_2008_Atmospheric_Chemistry_and_Physics.pdf PDF]
# Liu, C.-M.*, M.-T. Yeh, S. Paul, Y.-C. Lee, D.J. Jacob, '''T.-M. Fu''', J.-H. Woo, G.R. Carmichael, and D.G. Streets (2008), Effect of anthropogenic emissions in East Asia on regional ozone levels during spring cold continental outbreaks near Taiwan: a case study, ''Environ. Model. Software'', 23(5), 579-591, doi:10.1016/j.envsoft.2007.08.007.[https://atmoschem.org.cn/papers/Liu_et_al_2008_Environmental_Modelling_and_Software.pdf PDF]
# Millet, D. B.*, D. J. Jacob, K. F. Boersma, '''T.-M. Fu''', T. P. Kurosu, K. Chance, C. L. Heald, and A. Guenther (2007), Spatial distribution of isoprene emissions from North America derived from formaldehyde column measurements by the OMI satellite sensor, ''J. Geophys. Res.'', 113, D02307, doi:10.1029/2007JD008950. [https://atmoschem.org.cn/papers/Millet_et_al_2007_Journal_of_Geophysical_Research.pdf PDF]
# '''Fu, T.-M.*''', D. J. Jacob, P. I. Palmer, K. Chance, Y. X. Wang, B. Barletta, D. R. Blake, J. C. Stanton, M. J. Pilling (2007), Space-based formaldehyde measurements as constraints on volatile organic compound emissions in East and South Asia, ''J. Geophys. Res.'', 112, D06312, doi:10.1029/2006JD007853. [https://atmoschem.org.cn/papers/Fu_et_al_2007_Journal_of_Geophysical_Research.pdf PDF]
# Wang, Y.X.*, M. B. McElroy, R. V. Martin, D. G. Streets, Q. Zhang, and '''T.-M. Fu''' (2007), Seasonal variability of NOx emissions over east China constrained by satellite observations: Implications for combustion and microbial sources, ''J. Geophys. Res.'', 112, D06301, doi:10.1029/2006JD007538. [https://atmoschem.org.cn/papers/Wang_et_al_2007_Journal_of_Geophysical_Research.pdf PDF]
# Sauvage, B.*, R. V. Martin, A. van Donkelaar, X. Liu, K. Chance, L. Jaegle, P. I. Palmer, S. Wu, and '''T.-M. Fu''' (2007), Remote sensed and in situ constraints on processes affecting tropical tropospheric ozone, ''Atmos. Chem. Phys.'', 7, 815-838, doi:10.5194/acp-7-815-2007. [https://atmoschem.org.cn/papers/Sauvage_et_al_2007_Atmospheric_Chemistry_and_Physics.pdf PDF]
# van Donkelaar, A.*, R. V. Martin, R. J. Park, C. L. Heald, '''T.-M. Fu''', H. Liao, and A. Guenther (2007), "Model evidence for a significant source of secondary organic aerosol from isoprene", ''Atmos. Environ.'', 41, 1267-1274. [https://atmoschem.org.cn/papers/van_Donkelaar_et_al_2007_Atmospheric_Environment.pdf PDF]
# Palmer, P. I.*, D. S. Abbot, '''T.-M. Fu''', D. J. Jacob, K. Chance, T. P. Kuruso, A. Guenther, C. Wiedinmyer, J. C. Stanton, M. J. Pilling, S. N. Pressley, B. Lamb, and A. L. Sumner (2006), Quantifying the seasonal and interannual variability of North American isoprene emissions using satellite observations of formaldehyde column, ''J. Geophys. Res.'', 111, D12315, doi:10.1029/2005JD006689. [https://atmoschem.org.cn/papers/Palmer_et_al_2006_Journal_of_Geophysical_Research.pdf PDF]
# Liu, X.*, K. Chance, C.E. Sioris, T.P. Kurosu, R,J.D. Spurr, R.V. Martin, '''T.-M. Fu''', J.A. Logan, D.J. Jacob, P.I. Palmer, M.J. Newchurch, I.A. Megretskaia, and R. Chatfield (2006), First directly-retrieved global distribution of tropospheric column ozone from GOME: comparison with the GEOS-CHEM model, ''J. Geophys. Res.'', 111, D02308. [https://atmoschem.org.cn/papers/Liu_et_al_2006_Journal_of_Geophysical_Research.pdf PDF]
# Jiang, X., Q. Xu, S. K. W. Dertinger, A. D. Stroock, '''T.-M. Fu''', and G. M. Whitesides *(2005), A general method for patterning gradients of biomolecules on surfaces using microfluidic networks, ''Analytical Chemistry'', 77(8), 2338 – 2347, doi:10.1021/ac048440m.[https://atmoschem.org.cn/papers/Jiang_et_al_2005_Analytical_Chemistry.pdf PDF]
# '''Fu, T.-M.''', and J. P. Chen (2001), The intricate beauty of bubbles. National Science Council Monthly, 29(11), 788-796. (In Chinese)[https://atmoschem.org.cn/papers/Fu_et_al_2001_National_Science_Council_Monthly.pdf PDF]