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Journal of the Air & Waste Management Association Volume 56, 2006 - Issue 5
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Technical Paper

Pilot-Scale Study of the Effect of Selective Catalytic Reduction Catalyst on Mercury Speciation in Illinois and Powder River Basin Coal Combustion Flue Gases

Chun W. Lee Office of Research and Development, National Risk Management Research Laboratory, U.S. Environmental Protection Agency, Research Triangle Park, NC, USACorrespondence[email protected]
,
Ravi K. Srivastava Office of Research and Development, National Risk Management Research Laboratory, U.S. Environmental Protection Agency, Research Triangle Park, NC, USA
,
S. Behrooz Ghorishi Babcock & Wilcox, Alliance, OH, USA
,
Jarek Karwowski ARCADIS Geraghty & Miller, Inc., Research Triangle Park, NC, USA
,
Thomas W. Hastings Cormetech, Inc, Durham, NC, USA
&
Joseph C. Hirschi Illinois Clean Coal Institute, Carterville, IL, USA
Pages 643-649 | Published online: 29 Feb 2012

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Eric A. Morris, Kazuki Morita & Charles Q. Jia. (2010) Understanding the effects of sulfur on mercury capture from coal-fired utility flue gases. Journal of Sulfur Chemistry 31:5, pages 457-475.
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Articles from other publishers (35)

Yang Teng, Peixuan Li, Guangyu Wang, Chen Wang, Nana Qi, Kai Zhang & Minwu Wang. (2023) Effects of SCR catalyst breakage on mercury emission properties in coal-fired power plant: field testing and laboratory evaluation. Applied Catalysis A: General 650, pages 118962.
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Bing Li & Hongliang Wang. (2021) Effect of flue gas purification facilities of coal-fired power plant on mercury emission. Energy Reports 7, pages 190-196.
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Shibo Zhang, Qingzhu Zhang, Yongchun Zhao, Jianping Yang, Yang Xu & Junying Zhang. (2020) Enhancement of CeO 2 modified commercial SCR catalyst for synergistic mercury removal from coal combustion flue gas . RSC Advances 10:42, pages 25325-25338.
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Yingju Yang, Jing Liu & Zhen Wang. (2020) Reaction mechanisms and chemical kinetics of mercury transformation during coal combustion. Progress in Energy and Combustion Science 79, pages 100844.
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Yingju Yang, Jing Liu, Zhen Wang, Sen Miao, Junyan Ding, Yingni Yu & Jinchuan Zhang. (2019) A complete catalytic reaction scheme for Hg0 oxidation by HCl over RuO2/TiO2 catalyst. Journal of Hazardous Materials 373, pages 660-670.
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Jianping Yang, Wenbing Zhu, Shibo Zhang, Mingguang Zhang, Wenqi Qu, Hailong Li, Zhiyong Zeng, Yongchun Zhao & Junying Zhang. (2019) Role of flue gas components in Hg0 oxidation over La0.8Ce0.2MnO3 perovskite catalyst in coal combustion flue gas. Chemical Engineering Journal 360, pages 1656-1666.
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Chuanmin Chen, Wenbo Jia, Songtao Liu & Yue Cao. (2018) Simultaneous NO Removal and Hg 0 Oxidation over CuO Doped V 2 O 5 -WO 3 /TiO 2 Catalysts in Simulated Coal-Fired Flue Gas . Energy & Fuels 32:6, pages 7025-7034.
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Chuanmin Chen, Wenbo Jia, Songtao Liu & Yue Cao. (2018) The enhancement of CuO modified V2O5-WO3/TiO2 based SCR catalyst for Hg° oxidation in simulated flue gas. Applied Surface Science 436, pages 1022-1029.
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Chuanmin Chen, Wenbo Jia, Songtao Liu, Yue Cao, Bing Zhao & Jianqiao Wang. (2018) Catalytic performance of CuCl2-modified V2O5-WO3/TiO2 catalyst for Hg0 oxidation in simulated flue gas. Korean Journal of Chemical Engineering 35:3, pages 637-644.
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Guilong Chi, Boxiong Shen, Ranran Yu, Chuan He & Xiao Zhang. (2017) Simultaneous removal of NO and Hg 0 over Ce-Cu modified V 2 O 5 /TiO 2 based commercial SCR catalysts. Journal of Hazardous Materials 330, pages 83-92.
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Chun Wai Lee, Yongxin Zhao, Shengyong Lu & William R. Stevens. (2016) Catalytic Destruction of a Surrogate Organic Hazardous Air Pollutant as a Potential Co-benefit for Coal-Fired Selective Catalytic Reduction Systems. Energy & Fuels 30:3, pages 2240-2247.
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Chun-Hsiang Chiu, Hsing-Cheng Hsi & Hong-Ping Lin. (2015) Multipollutant control of Hg/SO2/NO from coal-combustion flue gases using transition metal oxide-impregnated SCR catalysts. Catalysis Today 245, pages 2-9.
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Li ZHAO, Qing-song HE, Lin LI, Qiang LU, Chang-qing DONG & Yong-ping YANG. (2015) Research on the catalytic oxidation of Hg0 by modified SCR catalysts. Journal of Fuel Chemistry and Technology 43:5, pages 628-634.
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Ana Suarez Negreira & Jennifer Wilcox. (2014) Uncertainty Analysis of the Mercury Oxidation over a Standard SCR Catalyst through a Lab-Scale Kinetic Study. Energy & Fuels 29:1, pages 369-376.
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Bingkai Zhang, Jing Liu, Guoliang Dai, Ming Chang & Chuguang Zheng. (2015) Insights into the mechanism of heterogeneous mercury oxidation by HCl over V2O5/TiO2 catalyst: Periodic density functional theory study. Proceedings of the Combustion Institute 35:3, pages 2855-2865.
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Robert Schreiber Jr.Shameem Hasan, Carrie Yonley & Charles D. Kellett. 2014. Mercury Control. Mercury Control 141 162 .
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Bo Zhao, Xiaowei Liu, Zijian Zhou, Haizhong Shao, Chao Wang, Junping Si & Minghou Xu. (2014) Effect of molybdenum on mercury oxidized by V2O5–MoO3/TiO2 catalysts. Chemical Engineering Journal 253, pages 508-517.
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Mengze Zhang, Peng Wang, Yong Dong, Hui Sui & Dongdong Xiao. (2014) Study of elemental mercury oxidation over an SCR catalyst with calcium chloride addition. Chemical Engineering Journal 253, pages 243-250.
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Yanshan Gao, Zhang Zhang, Jingwen Wu, Linhai Duan, Ahmad Umar, Luyi Sun, Zhanhu Guo & Qiang Wang. (2013) A Critical Review on the Heterogeneous Catalytic Oxidation of Elemental Mercury in Flue Gases. Environmental Science & Technology 47:19, pages 10813-10823.
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Pengying Wang, Sheng Su, Jun Xiang, Fan Cao, Lushi Sun, Song Hu & Siyuan Lei. (2013) Catalytic oxidation of Hg0 by CuO–MnO2–Fe2O3/γ-Al2O3 catalyst. Chemical Engineering Journal 225, pages 68-75.
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Wei Gao, Qingcai Liu, Chang-Yu Wu, Hailong Li, Ying Li, Jian Yang & Guofang Wu. (2013) Kinetics of mercury oxidation in the presence of hydrochloric acid and oxygen over a commercial SCR catalyst. Chemical Engineering Journal 220, pages 53-60.
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Hailong Li, Chang-Yu Wu, Ying Li, Liqing Li, Yongchun Zhao & Junying Zhang. (2012) Role of flue gas components in mercury oxidation over TiO2 supported MnOx-CeO2 mixed-oxide at low temperature. Journal of Hazardous Materials 243, pages 117-123.
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Hiroyuki Kamata & Akinori Yukimura. (2012) Catalyst aging in a coal combustion flue gas for mercury oxidation. Fuel Processing Technology 104, pages 295-299.
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Beatrice-Andreea Dranga, Liliana Lazar & Heinz Koeser. (2012) Oxidation Catalysts for Elemental Mercury in Flue Gases—A Review. Catalysts 2:1, pages 139-170.
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Hailong Li, Ying Li, Chang-Yu Wu & Junying Zhang. (2011) Oxidation and capture of elemental mercury over SiO2–TiO2–V2O5 catalysts in simulated low-rank coal combustion flue gas. Chemical Engineering Journal 169:1-3, pages 186-193.
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Jing Liu, Mingfeng He, Chuguang Zheng & Ming Chang. (2011) Density functional theory study of mercury adsorption on V2O5 (0 0 1) surface with implications for oxidation. Proceedings of the Combustion Institute 33:2, pages 2771-2777.
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Deepak Pudasainee, Sung Jun Lee, Sang-Hyeob Lee, Jeong-Hun Kim, Ha-Na Jang, Sung-Jin Cho & Yong-Chil Seo. (2010) Effect of selective catalytic reactor on oxidation and enhanced removal of mercury in coal-fired power plants. Fuel 89:4, pages 804-809.
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Yunjun Wang, Yufeng Duan, Liguo Yang, Changsui Zhao, Xianglin Shen, Mingyao Zhang, Yuqun Zhuo & Changhe Chen. (2009) Experimental study on mercury transformation and removal in coal-fired boiler flue gases. Fuel Processing Technology 90:5, pages 643-651.
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Keith Schofield. (2008) Fuel-Mercury Combustion Emissions: An Important Heterogeneous Mechanism and an Overall Review of its Implications. Environmental Science & Technology 42:24, pages 9014-9030.
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Hiroyuki Kamata, Shun-ichiro Ueno, Toshiyuki Naito & Akinori Yukimura. (2008) Mercury Oxidation over the V 2 O 5 (WO 3 )/TiO 2 Commercial SCR Catalyst . Industrial & Engineering Chemistry Research 47:21, pages 8136-8141.
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Sandhya Eswaran & Harvey G. Stenger. (2008) Effect of halogens on mercury conversion in SCR catalysts. Fuel Processing Technology 89:11, pages 1153-1159.
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Nick D. Hutson. (2007) Mercury Capture on Fly Ash and Sorbents: The Effects of Coal Properties and Combustion Conditions. Water, Air, & Soil Pollution: Focus 8:3-4, pages 323-331.
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Ying Li, Patrick D. Murphy, Chang-Yu Wu, Kevin W. Powers & Jean-Claude J. Bonzongo. (2008) Development of Silica/Vanadia/Titania Catalysts for Removal of Elemental Mercury from Coal-Combustion Flue Gas. Environmental Science & Technology 42:14, pages 5304-5309.
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Ye Zhuang, Jason Laumb, Richard Liggett, Mike Holmes & John Pavlish. (2007) Impacts of acid gases on mercury oxidation across SCR catalyst. Fuel Processing Technology 88:10, pages 929-934.
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