Behavior of Mercury Emissions from a Commercial Coal-Fired Power Plant: The Relationship between Stack Speciation and Near-Field Plume Measurements

• Published in: Environmental science & technology Vol. 48; no. 22; pp. 13540 - 13548
• Main Authors: Landis, Matthew S, Ryan, Jeffrey V, ter Schure, Arnout F. H, Laudal, Dennis
• Format: Journal Article
• Language: English
• Published: Washington, DC American Chemical Society 18.11.2014
• Subjects: Air Movements; Air Pollutants - analysis; Applied sciences; Atmospheric pollution; Coal - analysis; Coal-fired power plants; Combustion and energy production; Emissions; Environmental Monitoring - methods; Exact sciences and technology; Florida; Flue gas; Industrial plant emissions; Mercury; Mercury - analysis; Mercury - chemistry; Nitrogen Oxides - analysis; Oxidation-Reduction; Pollution; Pollution sources. Measurement results; Power Plants; Sulfur Dioxide - analysis; Florida; Pollutant behavior; Plume; Neurotoxic; Heavy metal; Gaseous effluent; Trace element; Coal power plant; Air pollution; Poison; Atmospheric dispersion; Emission measure; Mercury; Speciation
• ISSN: 0013-936X; 1520-5851
• DOI: 10.1021/es500783t

The reduction of divalent gaseous mercury (HgII) to elemental gaseous mercury (Hg0) in a commercial coal-fired power plant (CFPP) exhaust plume was investigated by simultaneous measurement in-stack and in-plume as part of a collaborative study among the U.S. EPA, EPRI, EERC, and Southern Company. In-stack continuous emission monitoring data were used to establish the CFPP’s real-time mercury speciation and plume dilution tracer species (SO2, NOX) emission rates, and an airship was utilized as an airborne sampling platform to maintain static position with respect to the exhaust plume centerline for semicontinuous measurement of target species. Varying levels of HgII concentration (2.39–3.90 μg m–3) and percent abundance (∼87–99%) in flue gas and in-plume reduction were observed. The existence and magnitude of HgII reduction to Hg0 (0–55%) observed varied with respect to the types and relative amounts of coals combusted, suggesting that exhaust plume reduction occurring downwind of the CFPP is influenced by coal chemical composition and characteristics.