Mercury stable isotope fractionation in six utility boilers of two large coal-fired power plants

Coal-fired utility boiler (CFUB) emissions of mercury (Hg) represent the largest anthropogenic Hg source to the atmosphere. Hg stable isotope signatures in coal have been shown to vary among coal deposits and coal basins. There is therefore a substantial interest in tracing CFUB Hg emissions at loca...

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Bibliographic Details
Published in:Chemical geology 2013-01, Vol.336, p.103-111
Main Authors: Sun, Ruoyu, Heimbürger, Lars-Eric, Sonke, Jeroen E., Liu, Guijian, Amouroux, David, Berail, Sylvain
Format: Article
Language:English
Subjects:
Coal
Coal combustion products
Isotopes
Mercury
Ocean, Atmosphere
Power plant
Sciences of the Universe
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Summary:Coal-fired utility boiler (CFUB) emissions of mercury (Hg) represent the largest anthropogenic Hg source to the atmosphere. Hg stable isotope signatures in coal have been shown to vary among coal deposits and coal basins. There is therefore a substantial interest in tracing CFUB Hg emissions at local, regional and global scales. However, CFUB operating conditions, Hg capture technologies and post-emission Hg transformations may potentially alter the original feed coal Hg isotope signatures. Here we investigate Hg isotopic fractionation between feed coal and coal combustion products in six utility boilers of two large power plants in Huainan City, Anhui Province, China. We observe identical trends in all six boilers: relative to feed coal with δ202Hg ranging from −0.67 to −0.18‰, oxidized Hg species in bottom ash and fly ash are enriched in the lighter isotopes with δ202Hg from −1.96 to −0.82‰. Flue gas desulphurization by-product gypsum shows δ202Hg from −0.99 to −0.47‰. No mass independent fractionation was observed during the transport and transformation of Hg inside the boilers. An isotope mass balance suggests that gaseous stack Hg emissions are enriched by up to 0.3‰ in the heavier Hg isotopes relative to feed coal and that the enrichment depends on the Hg capture technology. The observation that oxidized Hg species are enriched in the lighter isotopes suggests that oxidized and reduced forms of Hg in stack emission carry different isotope signatures. This has implications for near-field and far-field Hg emission tracing. [Display omitted] ► We investigated Hg stable isotope fractionation in two Chinese coal-fired power plants. ► A 2‰ variation of δ202Hg was observed in feed coal, bottom ash, fly ash and gypsum. ► No mass independent fractionation of Hg isotopes took place inside the boilers. ► Relative to feed coal, bottom ash and fly ash are enriched in the lighter isotopes. ► Calculated stack Hg emissions are slightly enriched in the heavier Hg isotopes relative to feed coal.
ISSN:0009-2541
1872-6836
DOI:10.1016/j.chemgeo.2012.10.055