Investigation of Mercury Transformation by HBr Addition in a Slipstream Facility with Real Flue Gas Atmospheres of Bituminous Coal and Powder River Basin Coal

Cao, Yan; Wang, Quanhai; Chen, Chien‐Wei; Chen, Bobby; Cohron, Martin; Tseng, † Yi-chuan; Chiu, Chengchung; Chu, and Paul; Pan, Wei‐Ping

doi:10.1021/ef060547k

Cited by 25 publications

(16 citation statements)

References 26 publications

(37 reference statements)

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“…2. This HCl concentration represented the concentration in a typical combustion of bituminous and sub-bituminous coal with medium chlorine content [27,28]. Our experimental results indicated that carrier gases evaluated in this study had significant effects on Hg-oxidation.…”

Section: Role Of Carrier Gas In Hg-oxidationmentioning

confidence: 56%

Homogeneous Mercury Oxidation under Simulated Flue Gas of Oxy-coal Combustion

Suriyawong¹,

Biswas²

2013

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This study investigated the effects of oxy-coal combustion on Hg-oxidation by HCl using simulated flue gas. Experiments were conducted with different carrier gases that one might find in oxy-coal combustion and conventional coal combustion. The extents of Hg-oxidation in pure CO2, pure N2 and air were also studied for comparison. Our experimental results demonstrated that CO2 weakly assisted Hg-oxidation by HCl; however, its significance was outweighed by the presence of O2. For all carrier gases, the presence of NO or H2O inhibited Hg-oxidation. The inhibitory effects strongly depended on concentrations of NO, but not moisture content. The synergistic inhibitory effects were shown when both NO and H2O were present together. The extents of Hg-oxidation were not significantly different for O2-N2, O2-N2-CO2 and O2-CO2 gas mixtures for all conditions investigated in this study.

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Section: Role Of Carrier Gas In Hg-oxidationmentioning

confidence: 56%

Homogeneous Mercury Oxidation under Simulated Flue Gas of Oxy-coal Combustion

Suriyawong¹,

Biswas²

2013

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“…380 °C) increased from a baseline of 18À42 to 96% when the measured bromine concentration in the flue gas increased to 3.5 ppmv. Energy & Fuels ARTICLE Cao et al 21,22 and Qu et al 23 suggested that the simultaneous presence of bromine and chlorine can affect mercury oxidation through the formation of the reactive interhalogen species, BrCl, and thus increase mercury oxidation relative to each halogen by itself. In this work, no such synergy between bromine and chlorine was observed.…”

Section: ' Resultsmentioning

confidence: 99%

Gas-Phase Oxidation of Mercury by Bromine and Chlorine in Flue Gas

et al. 2011

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Oxidized mercury species may be formed in combustion systems through gas-phase reactions between elemental mercury and halogens, such as chorine or bromine. This study examines how bromine and chlorine species affect mercury oxidation in the gas phase. Experiments were conducted in a bench-scale, laminar, methane-fired (300 W), quartz-lined reactor, in which gas composition (HCl, HBr, NO x , and SO 2 ) was varied. In the experiments, the postcombustion gases were quenched from the flame temperature to about 350°C and then speciated mercury was measured using a wet conditioning system and continuous emission monitor (CEM). Bromine was shown to be much more effective in the postflame, homogeneous oxidation of mercury than chlorine, on an equivalent molar basis. The addition of NO to the flame (up to 400 ppmv) had no impact on mercury oxidation by chlorine or bromine. The addition of SO 2 had no effect on mercury oxidation by chlorine at SO 2 concentrations below about 400 ppmv; some increase in mercury oxidation was observed at SO 2 concentrations of 400 ppmv and higher. The addition of chlorine caused minor increases in the extent of oxidation by bromine. The results of this study can be used to understand the relative importance of gasphase mercury oxidation by bromine in combustion systems.

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“…Cao et al 16,17 suggested that the simultaneous presence of bromine and chlorine can also affect the extent of mercury oxidation due to interhalogen species interactions with elemental mercury. Based on experimental oxidation levels that were higher than expected, they suggested that bromine is able to increase mercury oxidation kinetics by promoting the formation of activated chlorine.…”

Section: Effects Of Mixtures Of Bromine and Chlorine On Homogeneous Oxidationmentioning

confidence: 99%

Analysis of Halogen-Mercury Reactions in Flue Gas

Buitrago¹,

Silcox²,

Senior³

et al. 2010

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Oxidized mercury species may be formed in combustion systems through gas-phase reactions between elemental mercury and halogens, such as chorine or bromine. This study examines how bromine species affect mercury oxidation in the gas phase and examines the effects of mixtures of bromine and chlorine on extents of oxidation. Experiments were conducted in a bench-scale, laminar flow, methane-fired (300 W), quartz-lined reactor in which gas composition (HCl, HBr, NO x , SO 2 ) and temperature profile were varied. In the experiments, the post-combustion gases were quenched from flame temperatures to about 350 o C, and then speciated mercury was measured using a wet conditioning system and continuous emissions monitor (CEM). Supporting kinetic calculations were performed and compared with measured levels of oxidation.

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Investigation of Mercury Transformation by HBr Addition in a Slipstream Facility with Real Flue Gas Atmospheres of Bituminous Coal and Powder River Basin Coal

Cited by 25 publications

References 26 publications

Homogeneous Mercury Oxidation under Simulated Flue Gas of Oxy-coal Combustion

Homogeneous Mercury Oxidation under Simulated Flue Gas of Oxy-coal Combustion

Gas-Phase Oxidation of Mercury by Bromine and Chlorine in Flue Gas

Analysis of Halogen-Mercury Reactions in Flue Gas

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