Source-Specific Health Risk Analysis on Particulate Trace Elements: Coal Combustion and Traffic Emission As Major Contributors in Wintertime Beijing

Ru Jin Huang; Rui Cheng; Miao Jing; Lu Yang; Yongjie Li; Qi Chen; Yang Chen; Jin Yan; Chunshui Lin; Yunfei Wu; Renjian Zhang; Imad El Haddad; Andre S.H. Prevot; Colin D. O'Dowd; Junji Cao

doi:10.1021/acs.est.8b02091

Source-Specific Health Risk Analysis on Particulate Trace Elements: Coal Combustion and Traffic Emission As Major Contributors in Wintertime Beijing

Ru Jin Huang
, Rui Cheng
, Miao Jing
, Lu Yang
, Yongjie Li
, Qi Chen
, Yang Chen
, Jin Yan
, Chunshui Lin
, Yunfei Wu
, Renjian Zhang
, Imad El Haddad
, Andre S.H. Prevot
, Colin D. O'Dowd
, Junji Cao

人居环境与建筑工程学院

CAS - Institute of Earth Environment
Thermo Fisher Scientific, Inc.
University of Macau
Peking University
CAS - Chongqing Institute of Green and Intelligent Technology
University of Galway
CAS - Institute of Atmospheric Physics
Paul Scherrer Institute

科研成果: 期刊稿件 › 文章 › 同行评审

174 引用（Scopus）

摘要

Source apportionment studies of particulate matter (PM) link chemical composition to emission sources, while health risk analyses link health outcomes and chemical composition. There are limited studies to link emission sources and health risks from ambient measurements. We show such an attempt for particulate trace elements. Elements in PM_2.5 were measured in wintertime Beijing, and the total concentrations of 14 trace elements were 1.3-7.3 times higher during severe pollution days than during low pollution days. Fe, Zn, and Pb were the most abundant elements independent of the PM pollution levels. Chemical fractionation shows that Pb, Mn, Cd, As, Sr, Co, V, Cu, and Ni were present mainly in the bioavailable fraction. Positive matrix factorization was used to resolve the sources of particulate trace elements into dust, oil combustion, coal combustion, and traffic-related emissions. Traffic-related emission contributed 65% of total mass of the measured elements during low pollution days. However, coal combustion dominated (58%) during severe pollution days. By combining element-specific health risk analyses and source apportionment results, we conclude that traffic-related emission dominates the health risks by particulate trace elements during low pollution days, while coal combustion becomes equally or even more important during moderate and severe pollution days.

源语言	英语
页（从-至）	10967-10974
页数	8
期刊	Environmental Science and Technology
卷	52
期	19
DOI	https://doi.org/10.1021/acs.est.8b02091
出版状态	已出版 - 2 10月 2018

联合国可持续发展目标

此成果有助于实现下列可持续发展目标：

可持续发展目标 3 良好健康与福祉

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10.1021/acs.est.8b02091

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Huang, R. J., Cheng, R., Jing, M., Yang, L., Li, Y., Chen, Q., Chen, Y., Yan, J., Lin, C., Wu, Y., Zhang, R., El Haddad, I., Prevot, A. S. H., O'Dowd, C. D., & Cao, J. (2018). Source-Specific Health Risk Analysis on Particulate Trace Elements: Coal Combustion and Traffic Emission As Major Contributors in Wintertime Beijing. Environmental Science and Technology, 52(19), 10967-10974. https://doi.org/10.1021/acs.est.8b02091

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title = "Source-Specific Health Risk Analysis on Particulate Trace Elements: Coal Combustion and Traffic Emission As Major Contributors in Wintertime Beijing",

abstract = "Source apportionment studies of particulate matter (PM) link chemical composition to emission sources, while health risk analyses link health outcomes and chemical composition. There are limited studies to link emission sources and health risks from ambient measurements. We show such an attempt for particulate trace elements. Elements in PM2.5 were measured in wintertime Beijing, and the total concentrations of 14 trace elements were 1.3-7.3 times higher during severe pollution days than during low pollution days. Fe, Zn, and Pb were the most abundant elements independent of the PM pollution levels. Chemical fractionation shows that Pb, Mn, Cd, As, Sr, Co, V, Cu, and Ni were present mainly in the bioavailable fraction. Positive matrix factorization was used to resolve the sources of particulate trace elements into dust, oil combustion, coal combustion, and traffic-related emissions. Traffic-related emission contributed 65\% of total mass of the measured elements during low pollution days. However, coal combustion dominated (58\%) during severe pollution days. By combining element-specific health risk analyses and source apportionment results, we conclude that traffic-related emission dominates the health risks by particulate trace elements during low pollution days, while coal combustion becomes equally or even more important during moderate and severe pollution days.",

author = "Huang, \{Ru Jin\} and Rui Cheng and Miao Jing and Lu Yang and Yongjie Li and Qi Chen and Yang Chen and Jin Yan and Chunshui Lin and Yunfei Wu and Renjian Zhang and \{El Haddad\}, Imad and Prevot, \{Andre S.H.\} and O'Dowd, \{Colin D.\} and Junji Cao",

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Huang, RJ, Cheng, R, Jing, M, Yang, L, Li, Y, Chen, Q, Chen, Y, Yan, J, Lin, C, Wu, Y, Zhang, R, El Haddad, I, Prevot, ASH, O'Dowd, CD & Cao, J 2018, 'Source-Specific Health Risk Analysis on Particulate Trace Elements: Coal Combustion and Traffic Emission As Major Contributors in Wintertime Beijing', Environmental Science and Technology, 卷 52, 号码 19, 页码 10967-10974. https://doi.org/10.1021/acs.est.8b02091

TY - JOUR

T1 - Source-Specific Health Risk Analysis on Particulate Trace Elements

T2 - Coal Combustion and Traffic Emission As Major Contributors in Wintertime Beijing

AU - Huang, Ru Jin

AU - Cheng, Rui

AU - Jing, Miao

AU - Yang, Lu

AU - Li, Yongjie

AU - Chen, Qi

AU - Chen, Yang

AU - Yan, Jin

AU - Lin, Chunshui

AU - Wu, Yunfei

AU - Zhang, Renjian

AU - El Haddad, Imad

AU - Prevot, Andre S.H.

AU - O'Dowd, Colin D.

AU - Cao, Junji

PY - 2018/10/2

Y1 - 2018/10/2

N2 - Source apportionment studies of particulate matter (PM) link chemical composition to emission sources, while health risk analyses link health outcomes and chemical composition. There are limited studies to link emission sources and health risks from ambient measurements. We show such an attempt for particulate trace elements. Elements in PM2.5 were measured in wintertime Beijing, and the total concentrations of 14 trace elements were 1.3-7.3 times higher during severe pollution days than during low pollution days. Fe, Zn, and Pb were the most abundant elements independent of the PM pollution levels. Chemical fractionation shows that Pb, Mn, Cd, As, Sr, Co, V, Cu, and Ni were present mainly in the bioavailable fraction. Positive matrix factorization was used to resolve the sources of particulate trace elements into dust, oil combustion, coal combustion, and traffic-related emissions. Traffic-related emission contributed 65% of total mass of the measured elements during low pollution days. However, coal combustion dominated (58%) during severe pollution days. By combining element-specific health risk analyses and source apportionment results, we conclude that traffic-related emission dominates the health risks by particulate trace elements during low pollution days, while coal combustion becomes equally or even more important during moderate and severe pollution days.

AB - Source apportionment studies of particulate matter (PM) link chemical composition to emission sources, while health risk analyses link health outcomes and chemical composition. There are limited studies to link emission sources and health risks from ambient measurements. We show such an attempt for particulate trace elements. Elements in PM2.5 were measured in wintertime Beijing, and the total concentrations of 14 trace elements were 1.3-7.3 times higher during severe pollution days than during low pollution days. Fe, Zn, and Pb were the most abundant elements independent of the PM pollution levels. Chemical fractionation shows that Pb, Mn, Cd, As, Sr, Co, V, Cu, and Ni were present mainly in the bioavailable fraction. Positive matrix factorization was used to resolve the sources of particulate trace elements into dust, oil combustion, coal combustion, and traffic-related emissions. Traffic-related emission contributed 65% of total mass of the measured elements during low pollution days. However, coal combustion dominated (58%) during severe pollution days. By combining element-specific health risk analyses and source apportionment results, we conclude that traffic-related emission dominates the health risks by particulate trace elements during low pollution days, while coal combustion becomes equally or even more important during moderate and severe pollution days.

UR - https://www.scopus.com/pages/publications/85053658552

U2 - 10.1021/acs.est.8b02091

DO - 10.1021/acs.est.8b02091

M3 - 文章

C2 - 30185022

AN - SCOPUS:85053658552

SN - 0013-936X

VL - 52

SP - 10967

EP - 10974

JO - Environmental Science and Technology

JF - Environmental Science and Technology

IS - 19

ER -

Source-Specific Health Risk Analysis on Particulate Trace Elements: Coal Combustion and Traffic Emission As Major Contributors in Wintertime Beijing

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