Investigation of the Behavior of Mercury Compounds in Coal Combustion Products

Gerasimov, G. Ya.

doi:10.1007/s10891-005-0112-8

Cited by 11 publications

(6 citation statements)

References 23 publications

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“…Regardless of the dominant mechanism for mercury oxidation, it is well-known that the transformation from Hg 0 to Hg 2+ in flue gas is kinetically limited. For temperatures below ∼450 °C, at equilibrium, nearly all mercury should exist as Hg 2+ ( , ). Due to the excess of chlorine-containing species (HCl and Cl 2 ), HgCl 2 is assumed to be the dominant form of Hg 2+ .…”

Section: Mercury Oxidation Mechanismsmentioning

confidence: 99%

“…As the flue gas cools, some of the Hg 0 is oxidized, presumably to HgCl 2 because of the large excess of chlorine present in coal. The extent of mercury oxidation depends upon a number of factors, including combustion characteristics, coal composition (including chlorine content) ( − ), concentrations of other species (i.e., NO x and SO 2 ) ( , ) in the flue gas, and the time−temperature history ( , ). Both Hg 0 and Hg 2+ can enter the particulate phase by adsorption onto fly ash particles ( − ).…”

Section: Introductionmentioning

confidence: 99%

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Survey of Catalysts for Oxidation of Mercury in Flue Gas

Presto

Granite

2006

Environ. Sci. Technol.

494

389

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Methods for removing mercury from flue gas have received increased attention because of recent limitations placed on mercury emissions from coal-fired utility boilers by the U. S. Environmental Protection Agency and various states. A promising method for mercury removal is catalytic oxidation of elemental mercury (Hg0) to oxidized mercury (Hg2+), followed by wet flue gas desulfurization (FGD). FGD cannot remove Hg0, but easily removes Hg2+ because of its solubility in water. To date, research has focused on three broad catalyst areas: selective catalytic reduction catalysts, carbon-based materials, and metals and metal oxides. We review published results for each type of catalyst and also present a discussion on the possible reaction mechanisms in each case. One of the major sources of uncertainty in understanding catalytic mercury oxidation is a lack of knowledge of the reaction mechanisms and kinetics. Thus, we propose that future research in this area should focus on two major aspects: determining the reaction mechanism and kinetics and searching for more cost-effective catalyst and support materials.

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Section: Mercury Oxidation Mechanismsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Survey of Catalysts for Oxidation of Mercury in Flue Gas

Presto

Granite

2006

Environ. Sci. Technol.

494

389

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“…In the same study, the presence of oxygen is shown to modify this by interacting with the chlorine and reducing the dominance of the dichloride to 1200 K. Such calculations also are very dependent on an accurate and complete database for any species that may be relevant. For example, previous calculations that still incorporate a strong HgO(g) bond strength value based on the JANAF source (268 kJ mol -1 ) (14) or have elements present that have a significant affinity for chlorine or bromine, will erode the thermodynamically expected dominant role for the gaseous dihalides (36)(37)(38). However, as will be seen, this is quite irrelevant and very misleading as the formation in the gas phase of such dihalides is kinetically constrained.…”

Section: Previous Proposed Mechanismsmentioning

confidence: 99%

Fuel-Mercury Combustion Emissions: An Important Heterogeneous Mechanism and an Overall Review of its Implications

Schofield

2008

Environ. Sci. Technol.

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An extensive examination of combustion gases containing trace amounts of mercury shows unambiguously mercury's propensity for heterogeneous chemistry. Although additional mechanisms for the oxidation chemistry of mercury have been implied by the continuing inadequacy of modeling attempts, details of the specific chemistry have remained unknown. Now it is shown that mercury can efficiently chemi-deposit onto surfaces encountered in practical combustors. If sulfur is present, condensed mercuric sulfate forms momentarily. This is then converted by gaseous HCl to HgCl2 that may sublime into the flow or be retained. This elusive and efficient noncatalytic mechanism most likely explains the observed fractional conversions to the dichloride observed in coal combustors. A receptive surface acts solely as an intermediary, facilitating the conversion while disguising its role. Without sulfur, a corresponding mechanism occurs but via HgO that is similarly converted to the dihalide. Such heterogeneous dynamics have significant repercussions for both full-scale combustors and bench-type experiments, which data have been reassessed and reviewed. Conclusions imply that observations concerning mercury will be system dependent and no two combustors can be exactly alike. The re-examination of prior work provides significant support for these conclusions. This fundamental understanding now lays a foundation for meaningful interpretations and program planning. It has indicated also the extreme care needed in sampling and monitoring the speciation of mercury in such combustion flows for reliable results. It now points to a simple low-cost surface-induced mitigation method for effectively converting the mercury in flue gases to the water-soluble dichloride. It is in essence no more than an optimization of the natural process that is currently occurring in combustors but to only limited degrees.

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“…Industrial research results confirm that mercury emission to the atmosphere depend on several factors (Hall et al, 1991;Galbreath & Zygarlicke, 2000;Gerasimov, 2005;Zhang et al, 2008). These include: mercury content and chemical composition of combusted coal, type of boiler, mercury speciation of flue gases leaving boiler, types and efficiency of exhaust gas purification processes and presence of specified components in fly ashes and flue gases.…”

Section: Introductionmentioning

confidence: 89%

Mercury in Bituminous Coal Used in Polish Power Plants

Burmistrz¹,

Kogut²

2016

Archives of Mining Sciences

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MERCURY IN BITUMINOUS COAL USED IN POLISH POWER PLANTS RTĘĆ W WĘGLACH KAMIENNYCH SPALANYCH W POLSKICH ELEKTROWNIACH I ELEKTROCIEPŁOWNIACHPoland is a country with the highest anthropogenic mercury emission in the European Union. According to the National Centre for Emissions Management (NCEM) estimation yearly emission exceeds 10 Mg. Within that approximately 56% is a result of energetic coal combustion. In 121 studied coal samples from 30 coal mines an average mercury content was 112.9 ppb with variation between 30 and 321 ppb. These coals have relatively large contents of chlorine and bromine. Such chemical composition is benefitial to formation of oxidized mercury Hg 2+ , which is easier to remove in Air Pollution Control Devices. The Hg r /Q i r (mercury content to net calorific value in working state) ratio varied between 1.187 and 13.758 g Hg · TJ -1 , and arithmetic mean was 4.713 g Hg · TJ -1 . Obtained results are close to the most recent NCEM mercury emission factor of 1.498 g Hg · TJ -1 . Value obtained by us is more reliable that emission factor from 2011 (6.4 g Hg · TJ -1 ), which caused overestimation of mercury emission from energetic coal combustion.

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Investigation of the Behavior of Mercury Compounds in Coal Combustion Products

Cited by 11 publications

References 23 publications

Survey of Catalysts for Oxidation of Mercury in Flue Gas

Survey of Catalysts for Oxidation of Mercury in Flue Gas

Fuel-Mercury Combustion Emissions: An Important Heterogeneous Mechanism and an Overall Review of its Implications

Mercury in Bituminous Coal Used in Polish Power Plants

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