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Wilcox, Jennifer, Robles, Joe, Marsden, David C. J., Blowers, Paul (2003) Theoretically Predicted Rate Constants for Mercury Oxidation by Hydrogen Chloride in Coal Combustion Flue Gases. Environmental Science & Technology, 37 (18). 4199-4204 doi:10.1021/es034025k

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Reference TypeJournal (article/letter/editorial)
TitleTheoretically Predicted Rate Constants for Mercury Oxidation by Hydrogen Chloride in Coal Combustion Flue Gases
JournalEnvironmental Science & Technology
AuthorsWilcox, JenniferAuthor
Robles, JoeAuthor
Marsden, David C. J.Author
Blowers, PaulAuthor
Year2003 (September)Volume37
Issue18
PublisherAmerican Chemical Society (ACS)
DOIdoi:10.1021/es034025kSearch in ResearchGate
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Mindat Ref. ID9396341Long-form Identifiermindat:1:5:9396341:3
GUID0
Full ReferenceWilcox, Jennifer, Robles, Joe, Marsden, David C. J., Blowers, Paul (2003) Theoretically Predicted Rate Constants for Mercury Oxidation by Hydrogen Chloride in Coal Combustion Flue Gases. Environmental Science & Technology, 37 (18). 4199-4204 doi:10.1021/es034025k
Plain TextWilcox, Jennifer, Robles, Joe, Marsden, David C. J., Blowers, Paul (2003) Theoretically Predicted Rate Constants for Mercury Oxidation by Hydrogen Chloride in Coal Combustion Flue Gases. Environmental Science & Technology, 37 (18). 4199-4204 doi:10.1021/es034025k
In(2003, September) Environmental Science & Technology Vol. 37 (18) American Chemical Society (ACS)

See Also

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Wilcox, Jennifer, Blowers, Paul (2004) Decomposition of Mercuric Chloride and Application to Combustion Flue Gases. Environmental Chemistry, 1 (3) 166 doi:10.1071/en04036
Galbreath, Kevin C., Zygarlicke, Christopher J. (1996) Mercury Speciation in Coal Combustion and Gasification Flue Gases. Environmental Science & Technology, 30 (8). 2421-2426 doi:10.1021/es950935t
Wilcox, Jennifer, Blowers, Paul (2004) Some comments on ‘A study on the reaction mechanism and kinetic of mercury oxidation by chlorine species’ [J. Mol. Struct. (Theochem) 625 (2003) 277]☆. Journal of Molecular Structure: THEOCHEM, 674. 275-278 doi:10.1016/j.theochem.2004.01.017
Urban, David R., Wilcox, Jennifer (2006) A Theoretical Study of Properties and Reactions Involving Arsenic and Selenium Compounds Present in Coal Combustion Flue Gases. The Journal of Physical Chemistry A, 110 (17). 5847-5852 doi:10.1021/jp055564+
Li, Hailong, Wu, Chang-Yu, Li, Ying, Zhang, Junying (2011) CeO2–TiO2Catalysts for Catalytic Oxidation of Elemental Mercury in Low-Rank Coal Combustion Flue Gas. Environmental Science & Technology, 45 (17). 7394-7400 doi:10.1021/es2007808
Presto, Albert A., Granite, Evan J. (2006) Survey of Catalysts for Oxidation of Mercury in Flue Gas. Environmental Science & Technology, 40 (18). 5601-5609 doi:10.1021/es060504i
Liu, Yan, Kelly, David J. A., Yang, Hongqun, Lin, Christopher C. H., Kuznicki, Steve M., Xu, Zhenghe (2008) Novel Regenerable Sorbent for Mercury Capture from Flue Gases of Coal-Fired Power Plant. Environmental Science & Technology, 42 (16). 6205-6210 doi:10.1021/es800532b
Lim, Dong-Hee, Wilcox, Jennifer (2013) Heterogeneous Mercury Oxidation on Au(111) from First Principles. Environmental Science & Technology, 47 (15). 8515-8522 doi:10.1021/es400876e
Zhuang, Ye, Thompson, Jeffrey S., Zygarlicke, Christopher J., Pavlish, John H. (2004) Development of a Mercury Transformation Model in Coal Combustion Flue Gas. Environmental Science & Technology, 38 (21). 5803-5808 doi:10.1021/es030683t
Everaert, K., Baeyens, J., Degrève, J. (2003) Entrained-Phase Adsorption of PCDD/F from Incinerator Flue Gases. Environmental Science & Technology, 37 (6). 1219-1224 doi:10.1021/es020020w
Kim, Bo Gyeong, Li, Xinxin, Blowers, Paul (2009) Adsorption Energies of Mercury-Containing Species on CaO and Temperature Effects on Equilibrium Constants Predicted by Density Functional Theory Calculations. Langmuir, 25. 2781-2789 doi:10.1021/la803310w
 
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