论文信息 - Geochemical database of feed coal and coal combustion products (CCPs) from five power plants in the United States

Geochemical database of feed coal and coal combustion products (CCPs) from five power plants in the United States

The principal mission of the U.S. Geological Survey (USGS) Energy Resources Program (ERP) is to (1) understand the processes critical to the formation, accumulation, occurrence, and alteration of geologically based energy resources; (2) conduct scientifically robust assessments of those resources; and (3) study the impacts of energy resource occurrence and (or) their production and use on both the environment and human health. The ERP promotes and supports research resulting in original, geology-based, non-biased energy information products for policy and decision makers, land and resource managers, other Federal and State agencies, the domestic energy industry, foreign governments, non-governmental groups, and academia. Investigations include research on the geology of oil, gas, and coal, and the impacts associated with energy resource occurrence, production, quality, and utilization. The ERP’s focus on coal is to support investigations into current issues pertaining to coal production, beneficiation and (or) conversion, and the environmental impact of the coal combustion process and coal combustion products (CCPs). To accomplish these studies, the USGS combines its activities with other organizations to address domestic and international issues that relate to the development and use of energy resources.

[1] D. Sengupta,et al. Radioelemental study of Kolaghat, thermal power plant, West Bengal, India: possible environmental hazards. , 2003 .

[2] H. Ipek,et al. The investigation of grinding kinetics of power plant solid fossil fuel in ball mill , 2010 .

[3] R. Finkelman,et al. Composition and Trace Element Content of Coal in Taiwan , 2005 .

[4] M. Yossifova,et al. Mineralogy and environmental geochemistry of lagooned ashes resulted from combustion of Maritza East lignite, Bulgaria , 2007 .

[5] J. Po,et al. Emanation coefficients for Rn in sized coal fly ash. , 1985 .

[6] F. Murray. The accumulation by plants of emissions from a coal-fired power plant , 1984 .

[7] Zhu Zhen. Research on Characteristics of Mercury Distribution in Combustion Products for A 300MW Pulverized Coal Fired Boiler , 2002 .

[8] John H. Pavlish,et al. Preface to the AQVI special issue of fuel processing technologies entitled: Air quality VI: Mercury, trace elements, SO3, particulate matter, and greenhouse gases , 2009 .

[9] V. Hoffmann,et al. Rock magnetic, mineralogical and microstructural characterization of fly ashes from Bulgarian power plants and the nearby anthropogenic soils , 2004 .

[10] R. Finkelman,et al. Potentially hazardous elements in coal: Modes of occurrence and summary of concentration data for coal components , 1998 .

[11] T. R. Carey,et al. Modeling Mercury Removal by Sorbent Injection. , 1999, Journal of the Air & Waste Management Association.

[12] W. H. Buttermore,et al. Trace elements in coal and coal wastes , 1989 .

[13] Joel Martinez-Frias,et al. A Coal-Fired Power Plant With Zero Atmospheric Emissions , 2003 .

[14] K. Galvin,et al. Development of Water-Based Methods for Determining Coal Washability Data , 2008 .

[15] Minghou Xu,et al. Size distributions of major elements in residual ash particles from coal combustion , 2009 .

[16] Edward S. Rubin,et al. A National Analysis of Toxic Released from Electric Power Plants , 1999 .

[17] Jyoti Singh,et al. Impact of Coal Power Plant Emission on the Foliar Elemental Concentrations in Plants in a Low Rainfall Tropical Region , 2000 .

[18] Andrew P. Jones,et al. Mercury Capture and Fate Using Wet FGD at Coal-Fired Power Plants , 2006 .

[19] John R. Bunt,et al. A new dissection methodology and investigation into coal property transformational behaviour impacting on a commercial-scale Sasol-Lurgi MK IV fixed-bed gasifier , 2006 .

[20] Tadashi Ito,et al. Control of ash deposition in pulverized coal fired boiler , 2009 .

[21] C. Sheng,et al. Comparison of sulphur retention by coal ash in different types of combustors , 2000 .

[22] B. Kansal,et al. Effect of fly-ash application on yield and nutrient composition of rice, wheat and on pH and available nutrient status of soils , 1995 .

[23] E. D. Harward,et al. RADIOACTIVITY FROM FOSSIL FUEL AND NUCLEAR POWER PLANTS. , 1970 .

[24] Wallace B. Smith,et al. Results of Field Measurements of Industrial Particulate Sources and Electrostatic Precipitator Performance. , 1975 .

[25] J. Burken,et al. The leaching characteristics of selenium from coal fly ashes. , 2007, Journal of environmental quality.

[26] Edward N. Steadman,et al. Barriers to the increased utilization of coal combustion/desulfurization by-products by government and commercial sectors - Update 1998 , 1999 .

[27] Robert H. Hurt,et al. Mercury capture by native fly ash carbons in coal-fired power plants. , 2010, Progress in energy and combustion science.

[28] Isam H. Aljundi,et al. Energy and exergy analysis of a steam power plant in Jordan , 2009 .

[29] Terry Wall,et al. Ash liberation from included minerals during combustion of pulverized coal: The relationship with char structure and burnout , 1999 .

[30] Studies of sintering of coal ash relevant to pulverized coal utility boilers: 1. Examination of the Raask shrinkage—electrical resistance method , 1984 .

[31] E. Wu,et al. Chemical form and leachability of inorganic trace elements in coal ash: Final report , 1987 .

[32] Wgj Dupree,et al. UNITED STATES ENERGY THROUGH THE YEAR 2000 , 1975 .

[33] Jingkun Jiang,et al. [Development of mercury emission inventory from coal combustion in China]. , 2005, Huan jing ke xue= Huanjing kexue.

[34] S. Niksa,et al. Kinetic modeling of homogeneous mercury oxidation: the importance of NO and H2O in predicting oxidation in coal-derived systems. , 2001, Environmental science & technology.

[35] Tim Cockerill,et al. Life cycle analysis of UK coal fired power plants , 2008 .

[36] Andrew P. Jones,et al. Developing mercury control technology for coal-fired power plants - from concept to commercial reality , 2008 .

[37] Bradley Adams,et al. Curbing the blue plume : SO3 formation and mitigation , 2006 .

[38] Kim Dam-Johansen,et al. Advanced Analytical Characterization of Coal Ashes—An Idemitsu Kosan—Elsam Cooperation Project , 2002 .

[39] J. Hower,et al. Characterization of Fly Ash from Low-Sulfur and High-Sulfur Coal Sources: Partitioning of Carbon and Trace Elements with Particle Size , 1999 .

[40] Jochen Ströhle,et al. A Vectorised Lagrangian Particle Model for the Numerical Simulation of Coal-Fired Furnaces , 2003 .

[41] D. Hoede,et al. Leaching Characteristics of Selected Elements from Coal Fly Ash as a Function of the Acidity of the Contact Solution and the Liquid/Solid Ratio , 1989 .

[42] V. Bashkin,et al. Environmental fluxes of arsenic from lignite mining and power generation in northern Thailand , 2002 .

[43] J. Hower,et al. Intra- and inter-unit variation in fly ash petrography and mercury adsorption: Examples from a western Kentucky power station , 2000 .

[44] L. Petrik,et al. Neutralization of acid mine drainage using fly ash , and strength development of the resulting solid residues , 2009 .

[45] Chuguang Zheng,et al. An economic feasibility study of O2/CO2 recycle combustion technology based on existing coal-fired power plants in China , 2009 .

[46] R. Bryers,et al. An Examination of the Relationship Between Ash Chemistry and Ash Fusion Temperatures in Various Coal Size and Gravity Fractions Using Polynomial Regression Analysis , 1976 .

[47] Health costs associated with the mining, transport and combustion of coal in the steam-electric industry , 1974, Nature.

[48] B. D. Tripathi,et al. Removal and accumulation of mercury by aquatic macrophytes from an open cast coal mine effluent. , 2009, Journal of hazardous materials.

[49] P. Mukhopadhyay,et al. Mineralogical speciation of elements in an eastern Canadian feed coal and their combustion residues from a Canadian power plant , 1996 .

[50] F. Lockwood,et al. Combustion measurements in a pulverised coal-fired furnace , 1988 .

[51] K. Nakajima,et al. Removal of boron from coal fly ash by washing with HCl solution , 2009 .

[52] J. Garty. Metal amounts in the lichen Ramalina duriaei (De Not.) Bagl. transplanted at biomonitoring sites around a new coal-fired power station after 1 year of operation. , 1987, Environmental research.

[53] Bongjin Jung. Sintering characteristics of low-rank coal ashes , 1996 .

[54] Br Stanmore. Ash Hopper Explosions in Coal-fired Boilers , 1990 .

[55] W. Kalkreuth,et al. Chemical characterization of feed coals and combustion-by-products from Brazilian power plants , 2008 .

[56] S. Al-Abed,et al. Influence of trace metal distribution on its leachability from coal fly ash , 2008 .

[57] T. D. Brown,et al. Inert coal macerals in combustion , 1977 .

[58] J. A. Cooper,et al. The mutagenic activity of particulate organic matter collected with a dilution sampler at coal-fired power plants. , 1987, JAPCA.

[59] P. Sinclair. Power plant plume NOx reactions and the reaction zone concept , 1984 .

[60] M. P. Bahor,et al. Economic analysis of wet versus dry ash disposal systems. Final report Jan 79-Sep 80 , 1981 .

[61] D. D. Davis,et al. Trace Gas Analysis of Power Plant Plumes Via Aircraft Measurement: O3, NOx, and SO2 Chemistry , 1974, Science.

[62] Bruce W. Smith. Analysis of the Location of Coal-Fired Power Plants in the Eastern United States , 1973 .

[63] J. T. Riley,et al. An Investigation of Mercury Emission from FBC Systems Fired with High-Chlorine Coals , 2001 .

[64] Edward S. Rubin,et al. Optimization of environmental control system design for an IGCC power plant , 1996 .

[65] A. Doukelis,et al. Oxyfuel boiler design in a lignite-fired power plant , 2007 .

[66] M. Hutton,et al. The leachability and chemical speciation of selected trace elements in fly ash from coal combustion and refuse incineration. , 1987, Environmental Pollution.

[67] J. Bird. Dry scrubbing technologies for flue gas desulfurization , 1998 .

[68] C. A. Evans,et al. Toxic Trace Elements: Preferential Concentration in Respirable Particles , 1974, Science.

[69] W. R. Kelly,et al. Tracing emissions from coal-fired power plants with enriched rare earth isotopes , 1993 .

[70] F. Goodarzi. Morphology and chemistry of fine particles emitted from a Canadian coal-fired power plant , 2006 .

[71] A. Leventhal,et al. Estimating the effect of air pollution from a coal-fired power station on the development of children's pulmonary function. , 2007, Environmental research.

[72] D. Kane,et al. Toxic trace elements associated with airborne particulate matter: a review. , 1987, JAPCA.

[73] Antti Tourunen,et al. Experimental trends of NO in circulating fluidized bed combustion , 2009 .

[74] H. Sutcu. Coal Desulfurization Using Natural Ca-Based Sorbents , 2004 .

[75] T. García,et al. Toxic organic emissions from coal combustion , 2000 .

[76] W. P. Miller,et al. Contaminant Mobility in Soil Columns Amended with Fly Ash and Flue Gas Desulfurization Gypsum , 1999 .

[77] P. Froelich,et al. Arsenic, selenium, and antimony: from coal fired power plants to the Chattahoochee River , 2003 .

[78] John M. Sweeten,et al. The economics of reburning with cattle manure-based biomass in existing coal-fired power plants for NOx and CO2 emissions control , 2009 .

[79] L. Gough,et al. Influence of a Coal-Fired Powerplant on the Element Content of Parmelia chlorochroa , 1977 .

[80] Adel F. Sarofim,et al. Fossil fuel combustion: A source book , 1991 .

[81] K. Oskarsson,et al. A Planner's Guide for Selecting Clean-Coal Technologies for Power Plants , 1997 .

[82] G. Blythe,et al. Ultra-high velocity testing on the TECo Big Bend Unit 4 FGD system , 1996 .

[83] W. Godbeer,et al. The Deposition of Trace Elements in the Environs of a Power Station , 1995 .

[84] K. Osinubi. Stabilisation of Tropical Black Clay with Cement and Pulverised Coal Bottom Ash Admixture , 2000 .

[85] B. D. Tripathi,et al. Magnetic mapping of fly-ash pollution and heavy metals from soil samples around a point source in a dry tropical environment , 2008, Environmental monitoring and assessment.

[86] Judith C. Chow,et al. Review of PM2.5 and PM10 Apportionment for Fossil Fuel Combustion and Other Sources by the Chemical Mass Balance Receptor Model , 2002 .

[87] Prinya Chindaprasirt,et al. Workability and strength of lignite bottom ash geopolymer mortar. , 2009, Journal of hazardous materials.

[88] C. Ward,et al. Determination of glass content and estimation of glass composition in fly ash using quantitative X-ray diffractometry , 2006 .

[89] K. Ladwig,et al. Air-Substrate Mercury Exchange Associated with Landfill Disposal of Coal Combustion Products , 2006, Journal of the Air & Waste Management Association.

[90] J. Hower,et al. Mercury capture by fly ash : Study of the combustion of a high-mercury coal at a utility boiler , 2000 .

[91] Natural radioactive elements and heavy metals in coal, fly ash and bottom ash from a thermal power plant , 1993 .

[92] M. Mercedes Maroto-Valer,et al. Novel separation of the differing forms of unburned carbon present in fly ash using density gradient centrifugation , 1999 .

[93] Partitioning of trace elements in the flue gas from coal combustion , 2001 .

[94] K. Bertine,et al. Magnetite in sediments as an indicator of coal combustion , 1986 .

[95] D. Helsel. More than obvious: better methods for interpreting nondetect data. , 2005, Environmental science & technology.

[96] S. Küçükbayrak,et al. Characterization of coal fly ash for possible utilization in glass production , 2007 .

[97] Alfons Kather,et al. Post-combustion CO2 capture in coal-fired power plants: Comparison of integrated chemical absorption processes with piperazine promoted potassium carbonate and MEA , 2009 .

[98] J. M. Wheeldon,et al. An evaluation of the United Kingdom Clean Coal Power Generation Group`s air-blown gasification cycle , 1996 .

[99] W. Wilson,et al. FORMATION AND TRANSPORT OF OZONE AND AEROSOLS IN POWER PLANT PLUMES * , 1980 .

[100] T. D. Brown,et al. Demonstration of dry carbon-based sorbent injection for mercury control in utility ESPs and baghouses , 1997 .

[101] K. Jensen,et al. Uraninite and fullerene in atmospheric particulates. , 2002, Environmental science & technology.

[102] T. Theis,et al. Sorptive behavior of trace metals on fly ash in aqueous systems , 1977 .

[103] E. Borguet,et al. Impact of surface heterogeneity on mercury uptake by carbonaceous sorbents under UHV and atmospheric pressure. , 2002, Environmental science & technology.

[104] D. J. Seery,et al. Repowering with High Performance Power Plant Systems (HIPPS) , 1996 .

[105] S. Vassilev,et al. Occurrence, abundance and origin of minerals in coals and coal ashes , 1996 .

[106] R. Zielinski,et al. Mode of occurrence of arsenic in feed coal and its derivative fly ash, Black Warrior Basin, Alabama , 2007 .

[107] J. Ondov,et al. Behavior of natural radionuclides in western coal-fired power plants , 1978 .

[108] B. Białecka,et al. Hydrothermal synthesis of zeolites from Polish coal fly ash , 2005 .

[109] Ronald E. West,et al. Trace element behavior in coal-fired power plant , 1975 .

[110] Yufeng Duan,et al. Experimental study on mercury transformation and removal in coal-fired boiler flue gases , 2009 .

[111] A. Filippidis,et al. Environmentally Important Elements in Fly Ashes and Their Leachates of the Power Stations of Greece , 2002 .

[112] J. Hower,et al. Studies of relationship between petrography and elemental analysis with grindability for Kentucky coals , 2008 .

[113] Roger K. Seals,et al. UTILIZATION OF ASH FROM COAL-BURNING POWER PLANTS IN HIGHWAY CONSTRUCTION , 1973 .

[114] J. Hwang,et al. Mercury Speciation and Distribution in a 660-Megawatt Utility Boiler in Taiwan Firing Bituminous Coals , 2010, Journal of the Air & Waste Management Association.

[115] Mathematical modeling of ash deposition in pulverized fuel-fired combustors , 2000 .

[116] K. J. Shell,et al. A multi-media approach to permitting mercury releases from coal-fired power plants , 1995 .

[117] Tushar K. Ghosh,et al. Energy Resources and Systems , 2009 .

[118] S. Stefaniak,et al. Coal and Coal Combustion Products: Prospects for Future and Environmental Issues , 2006 .

[119] James C. Hower,et al. Changes in the quality of coal combustion by-products produced by Kentucky power plants, 1978 to 1997: consequences of Clean Air Act directives , 1999 .

[120] Pisupati,et al. An investigation on polycyclic aromatic hydrocarbon emissions from pulverized coal combustion systems , 2000, Journal of hazardous materials.

[121] R. Comans,et al. Modeling Arsenic and Selenium Leaching from Acidic Fly Ash by Sorption on Iron (Hydr)oxide in the Fly Ash Matrix , 1996 .

[122] B. Gullett,et al. Development of a Cl-impregnated activated carbon for entrained-flow capture of elemental mercury. , 2002, Environmental science & technology.

[123] Yun Yu,et al. Char characteristics and particulate matter formation during Chinese bituminous coal combustion , 2007 .

[124] P. Hobbs,et al. Particles and trace gases in the plume from a modern coal-fired power plant in the western United States and their effects on light extinction , 1983 .

[125] M. J. Dekkers,et al. Magnetic Properties of Low-Ca Fly Ash: A Rapid Tool for Fe-Assessment and a Survey for Potentially Hazardous Elements , 1991 .

[126] Evaluation of a three-dimensional model for the prediction of heat transfer in power station boilers , 1995 .

[127] A. Pina,et al. Study of coal ash deposition in an entrained flow reactor: Assessment of traditional and alternative slagging indices , 2007 .

[128] B. Folkedahl,et al. Characteristics and Behavior of Inorganic Constituents , 2008 .

[129] F. O. Simon,et al. Methods for sampling and inorganic analysis of coal , 1989 .

[130] H. Ban,et al. AMMONIA RELEASE CHARACTERISTICS FROM COAL COMBUSTION FLY ASH , 2002 .

[131] P. A. Baedecker. Methods for geochemical analysis , 1987 .

[132] G. Zeng,et al. Removal of elemental mercury by activated carbon impregnated with CeO2 , 2009 .

[133] M. C. Alvarez,et al. Assessment of radiological emissions from Spanish coal power plants: radioactive releases and associated risks. , 1989, Health physics.

[134] J. E. Cichanowicz,et al. Deactivation of the Vanadia Catalyst in the Selective Catalytic Reduction Process , 1990 .

[135] Dongsheng Shen,et al. Content, mobility and transfer behavior of heavy metals in MSWI bottom ash in Zhejiang province, China , 2010 .

[136] The Evolution of Particles in the Plume from a Large Coal-Fired Boiler with Flue Gas Desulfurization , 2000, Journal of the Air & Waste Management Association.

[137] L. Sloss. 96/03356 - Trace emissions from coal combustion: Measurement and control , 1996 .

[138] P. Pavasant,et al. Zeolite Formation from Coal Fly Ash and Its Adsorption Potential , 2009, Journal of the Air & Waste Management Association.

[139] I. Iskandar,et al. Sediment characteristics in the vicinity of the pulliam power plant, green bay, Wisconsin , 1975 .

[140] Enhancement of population doses due to production of electricity from brown coal in Poland , 1986 .

[141] A. Baba,et al. Effects of fly ash from coal-burning electrical utilities on ecosystem and utilization of fly ash , 2006 .

[142] Eugenio Schuster,et al. Optimization of coal-fired boiler SCRs based on modified support vector machine models and genetic algorithms , 2009 .

[144] J. D. Robertson,et al. Chemistry and petrology of fly ash derived from the co-combustion of western United States coal and tire-derived fuel , 2004 .

[145] E. Suuberg,et al. Evaluation of the effects of coal fly ash amendments on the toxicity of a contaminated marine sediment , 2009, Environmental toxicology and chemistry.

[146] J. C. Mora,et al. Methodology Used in the Radiological Assessment of a Coal‐Fired Power Plant , 2008 .

[147] F. Goodarzi. Petrology of subbituminous feed coal as a guide to the capture of mercury by fly ash—influence of depositional environment , 2005 .

[148] P. Cheung,et al. Numerical Simulation of Air Concentration and Deposition of Particulate Metals Emitted from a Copper Smelter and a Coal Fired Power Plant During the 2000 Field Experiments on Characterization of Anthropogenic Plumes , 2007 .

[149] R. D. Brown,et al. Pollution control at electric power stations: Comparisons for U.S. and Europe , 1983 .

[150] D. White,et al. Trace elements in sediments, water, and American coots (Fulica americana) at a coal-fired power plant in Texas, 1979–1982 , 1986, Bulletin of environmental contamination and toxicology.

[151] R. Finkelman. Modes of occurrence of potentially hazardous elements in coal: levels of confidence , 1994 .

[152] James C. Hower,et al. Impact of coal properties on coal combustion by-product quality: examples from a Kentucky power plant , 2004 .

[153] R. Zielinski,et al. Radionuclides in fly ash and bottom ash: improved characterization based on radiography and low energy gamma-ray spectrometry , 1998 .

[154] Ramasubramania Iyer. The surface chemistry of leaching coal fly ash. , 2002, Journal of hazardous materials.

[155] E. Petrovský,et al. Effect of different soil conditions on magnetic parameters of power-plant fly ashes , 2001 .

[156] David R. Shonnard,et al. An evaluation of greenhouse gas mitigation options for coal-fired power plants in the US Great Lakes States , 2010 .

[157] J. Wendt,et al. Partitioning of arsenic, selenium, and cadmium during the combustion of Pittsburgh and Illinois #6 coals in a self-sustained combustor , 2000 .

[158] James C. Hower,et al. An examination of fly ash carbon and its interactions with air entraining agent , 1997 .

[159] Martin L Hall,et al. Fly ash quality, past, present and future, and the effect of ash on the development of novel products , 2002 .

[160] J. M. Allen,et al. Size distribution of fine particulate emissions from a coal-fired power plant , 1976 .

[161] J. Anderson,et al. The chemistry, aerosol physics, and optical properties of a western coal-fired power plant plume☆ , 1981 .

[162] R. Vidic,et al. Impact of Fly Ash Composition on Mercury Speciation in Simulated Flue Gas , 2009, Journal of the Air & Waste Management Association.

[163] G. Nozdrenko,et al. Metallurgical application of hydrogen-containing gases produced by the plasma coal gasification process at an environmentally clean thermal power station , 1993 .

[164] F. Pavloudakis,et al. The effect of lignite quality variation on the efficiency of on-line ash analyzers , 2009 .

[165] M. Mastalerz,et al. An Approach Toward a Combined Scheme for the Petrographic Classification of Fly Ash: Revision and Clarification , 2005 .

[166] P. Masclet,et al. Polycyclic aromatic hydrocarbons emitted by power stations, and influence of combustion conditions , 1987 .

[167] C. Seigneur,et al. Formation and Evolution of Sulfate and Nitrate Aerosols in Plumes , 1982 .

[168] Cynthia G. Abeyta,et al. Application of techniques to identify coal-mine and power-generation effects on surface-water quality, San Juan River basin, New Mexico and Colorado , 1987 .

[169] Rajesh Kumar,et al. Estimation of radon exhalation rate, natural radioactivity and radiation doses in fly ash samples from Durgapur thermal power plant, West Bengal, India. , 2008, Journal of environmental radioactivity.

[170] J. D. Robertson,et al. Influence of flue-gas desulfurization systems on coal combustion by-product quality at kentucky power stations burning high-sulfur coal , 1998 .

[171] J. Tardif,et al. Radial Growth of Oak and Aspen Near a Coal-Fired Station, Manitoba, Canada , 2004 .

[172] Nikolai V. Khartchenko,et al. Advanced energy systems , 2013 .

[173] Hideki Yamamoto,et al. Zeolite synthesis from coal fly ash by hydrothermal reaction using various alkali sources , 2002 .

[174] D. J. Swaine. Trace elements in coal and their dispersal during combustion , 1994 .

[175] Loreal V. Heebink,et al. Effects of mercury emission control technologies using halogens on coal combustion product chemical properties. , 2010, Journal of environmental monitoring : JEM.

[176] Jiming Hao,et al. Fine particle and trace element emissions from an anthracite coal-fired power plant equipped with a bag-house in China , 2008 .

[177] Robert B. Finkelman,et al. Reliability and reproducibility of leaching procedures to estimate the modes of occurrence of trace elements in coal , 1994 .

[178] J. Amonette,et al. Concentrations and Distribution of Major and Selected Trace Elements in Size-Density Fractionated Fly Ashes , 1999 .

[179] J. A. Withum,et al. EVALUATION OF MERCURY EMISSIONS FROM COAL-FIRED FACILITIES WITH SCR AND FGD SYSTEMS , 2006 .

[180] E. Dismukes. Trace element control in electrostatic precipitators and fabric filters , 1994 .

[181] A. Boccaccini,et al. Preparation of low melting temperature glass–ceramics from municipal waste incineration fly ash , 2009 .

[182] Ajit Kumar Kolar,et al. 3‐E analysis of advanced power plants based on high ash coal , 2010 .

[183] M. Schure,et al. Surface area and porosity of coal fly ash , 1985 .

[184] R. Vandenberghe,et al. Mössbauer effect study of fly and bottom ashes from an electric generating plant , 2009 .

[185] P. Brown,et al. Arsenic immobilization by calcium arsenate formation , 1999 .

[186] J. T. Riley,et al. Analysis of polynuclear aromatic hydrocarbons from coal fly ash , 1998 .

[187] J. Choung,et al. Fine Coal Beneficiation using an Air Dense Medium Fluidized Bed , 2006 .

[188] T. Chiba,et al. Elemental characterization of particle size-density separated coal fly ash by spectrophotometry, ICP (inductively coupled plasma emission spectrometry), and scanning electron microscopy-energy dispersive x-ray analysis , 1987 .

[189] M. Díaz-Somoano,et al. Retention of trace elements using fly ash in a coal gasification flue gas , 2002 .

[190] Surinder Singh,et al. Radon monitoring in a thermal power plant , 2005 .

[191] H. Heinrichs. Trace element discharge from a brown coal fired power plant , 1982 .

[192] David J. Hassett,et al. Scientifically valid leaching of coal conversion solid residues to predict environmental impact , 1994 .

[193] R. P. Papilla,et al. Specification for integrated controls and monitoring for fossil power plants , 1991 .

[194] C. Ngamcharussrivichai,et al. Adsorptive removal of thiophene and benzothiophene over zeolites from Mae Moh coal fly ash , 2008 .

[195] J. A. Carter,et al. Trace element measurements at the coal-fired Allen Steam Plant: particle characterization , 1974 .

[196] P. Fellin,et al. The Nanticoke shoreline diffusion experiment, June 1978—IV. A. Oxidation of sulphur dioxide in a power plant plume. B. Ambient concentrations and transport of sulphur dioxide, particulate sulphate and nitrate, and ozone , 1982 .

[197] J. Hower,et al. Coal resources, production, and quality in the Eastern kentucky coal field: Perspectives on the future of steam coal production , 1994 .

[198] Richard W. Bryers,et al. Fireside slagging, fouling, and high-temperature corrosion of heat-transfer surface due to impurities in steam-raising fuels , 1996 .

[199] H. Beck. Radiation exposures due to fossil fuel combustion , 1989 .

[200] G. A. Ayçik,et al. Radioactivity measurements of coals and ashes from coalfired power plants in the southwestern part of Turkey , 1997 .

[201] A. Andren,et al. Emissions of vapor-phase fluorine and ammonia from the Columbia coal-fired power plant. , 1985, Environmental science & technology.

[202] H. Hattori,et al. Highly Active Absorbent for SO2 Removal Prepared from Coal Fly Ash , 1995 .

[203] M. Saxena,et al. Characteristics Variation of Coal Combustion Residues in an Indian Ash Pond , 2004, Waste management & research : the journal of the International Solid Wastes and Public Cleansing Association, ISWA.

[204] Craig T. Bowman,et al. Control of combustion-generated nitrogen oxide emissions: Technology driven by regulation , 1992 .

[205] Matteo C. Romano,et al. Coal-fired power plant with calcium oxide carbonation for postcombustion CO2 capture , 2009 .

[206] S. Vassilev. Contents, modes of occurrence and behaviour of chlorine and bromine in combustion wastes from coal-fired power stations , 2000 .

[207] Sven Kjær. Status and future of advanced PF power plants , 1996 .

[208] John H. Bullock,et al. Analytical methods utilized by the United States Geological Survey for the analysis of coal and coal combustion by-products , 2002 .

[209] L. Fan,et al. Mechanism of Arsenic Sorption by Hydrated Lime , 1997 .

[210] A. Page,et al. Fly ash-derived strontium as an index to monitor deposition from coal-fired power plants. , 1981, Science.

[211] L. Petrik,et al. Utilization of fly ash for treatment of coal mines wastewater : Solubility controls on major inorganic contaminants , 2008 .

[212] T. Hsu. Adsorption of an acid dye onto coal fly ash , 2008 .

[213] A. Takami,et al. Export of atmospheric mercury from Asia , 2005 .

[214] Chenn Q. Zhou,et al. Elemental mercury removal using a wet scrubber. , 1999 .

[215] Ming-Quan Zhang,et al. Evaluation of Mercury Emissions to the Atmosphere from Coal Combustion, China , 2002, Ambio.

[216] Steven A. Benson,et al. Comparison of inorganic constituents in three low-rank coals , 1985 .

[217] Chuguang Zheng,et al. Thermoeconomic diagnosis of a coal fired power plant , 2007 .

[218] M. A. López-Antón,et al. Arsenic and selenium capture by fly ashes at low temperature. , 2006, Environmental science & technology.

[219] Petros A. Pilavachi,et al. Multicriteria evaluation of power plants impact on the living standard using the analytic hierarchy process , 2008 .

[220] M. Hupa,et al. Reducing NOx Emissions Using Fuel Staging, Air Staging, and Selective Noncatalytic Reduction in Synergy , 2005 .

[221] L. Forney,et al. Fast reversible reactions in power plant plumes: Application to the nitrogen dioxide photolytic cycle , 1981 .

[222] P. Bange. Hidden photostationary equilibrium: A case study on the effect of monitor averaging on the calculated oxidation rate of NO to NO2 in the plume of a power plant , 1993 .

[223] J. Boreman. Surplus production, compensation, and impact assessments of power plants , 2000 .

[224] Kenneth S. Sajwan,et al. Trace Elements in Coal and Coal Combustion Residues , 1993 .

[225] K. Cen,et al. Transient, three-dimensional simulation of particle dispersion in flows around a circular cylinder Re = 140–260) , 2009 .

[226] Jahar Roy,et al. Predictive equations for CO2 emission factors for coal combustion, their applicability in a thermal power plant and subsequent assessment of uncertainty in CO2 estimation , 2009 .

[227] Luis F. Vilches,et al. Effect of carbonaceous matter contents on the fire resistance and mechanical properties of coal fly ash enriched mortars , 2008 .

[228] E. Voudrias,et al. Leachability of heavy metals in Greek fly ash from coal combustion , 1998 .

[229] D. Cazorla-Amorós,et al. Selective synthesis of zeolite briquettes from conformed ashes , 2002 .

[230] Christophe Pécheyran,et al. Volatile metal species in coal combustion flue gas. , 2002, Environmental science & technology.

[231] Bruce G. Miller,et al. Evaluation of a hybrid sampling train for measuring trace elements and identifying mercury species in combustion flue gas , 1999 .

[232] O. Raabe,et al. Physical factors affecting the mutagenicity of fly ash from a coal-fired power plant. , 1979, Science.

[233] M. L. Moon. Overview of the Chalk Point Cooling Tower Project, 1972-1979 , 1979 .

[234] Judith Meyer,et al. Using trace element concentrations in Corbicula fluminea to identify potential sources of contamination in an urban river. , 2008, Environmental pollution.

[235] Hidajet Paçarizi,et al. Effects of pollution on lead and cadmium concentration and correlation with biochemical parameters in blood of human population nearby Kosovo thermo power plants , 2008 .

[236] C. Block,et al. Study of fly-ash emission during combustion of coal , 1976 .

[237] J. Schubel,et al. Power plant entrainment : a biological assessment , 1978 .

[238] Aldo Steinfeld,et al. Fuel saving, carbon dioxide emission avoidance, and syngas production by tri-reforming of flue gases from coal- and gas-fired power stations, and by the carbothermic reduction of iron oxide , 2006 .

[239] A. Sarofim,et al. Emissions of mercury, trace elements, and fine particles from stationary combustion sources , 2000 .

[240] J. Fardy,et al. Neutron activation analysis and radioactivity measurements of Australian coals and fly ashes , 1989 .

[241] R. A. Ashworth,et al. Developments in staged combustor technology , 1996 .

[242] D. Natusch. Potentially carcinogenic species emitted to the atmosphere by fossil-fueled power plants. , 1978, Environmental health perspectives.

[243] Gurdeep Singh,et al. Mathematical Modeling of Leachates from Ash Ponds of Thermal Power Plants , 2007, Environmental monitoring and assessment.

[244] D. Cazorla-Amorós,et al. Application of zeolitic material synthesised from fly ash to the decontamination of waste water and flue gas , 2002 .

[245] R. Vidic,et al. Adsorption Technology for Mercury Control in Flue Gases , 1995 .

[246] J. Hopper,et al. Trace metal capture by various sorbents during fluidized bed coal combustion , 1996 .

[247] Prakash Karamchandani,et al. Simulation of Sulfate and Nitrate Chemistry in Power Plant Plumes. , 1999, Journal of the Air & Waste Management Association.

[248] J. Hower,et al. Controls on boron and germanium distribution in the low-sulfur Amos coal bed, Western Kentucky coalfield, USA , 2002 .

[249] R. Filby,et al. Trace element concentration as a function of particle size in fly ash from a pulverized coal utility boiler. , 1985, Environmental science & technology.

[250] G. Versteeg,et al. CO2 capture from power plants. Part I: A parametric study of the technical performance based on monoethanolamine , 2007 .

[251] Y. Nathan,et al. Characterization of coal fly ash from Israel , 1999 .

[252] R. Meij. Prediction of Environmental Quality of By-Products of Coal-Fired Power Plants: Elemental Composition and Leaching , 1997 .

[253] A. Alva,et al. Leaching of Metals from Soils Amended with Fly Ash and Organic Byproducts , 1999 .

[254] Luis F. Vilches,et al. Development of new fire-proof products made from coal fly ash: the CEFYR project† , 2002 .

[255] M. Singh,et al. A scavenging model analysis around a large coal-fired power plant in New Delhi with a particular reference to the scavenging action of the monsoonal rains , 1987 .

[256] J. J. Helble,et al. TOXIC SUBSTANCES FROM COAL COMBUSTION , 1998 .

[257] F. Huggins,et al. Monitoring the species of arsenic, chromium and nickel in milled coal, bottom ash and fly ash from a pulverized coal-fired power plant in western Canada. , 2001, Journal of environmental monitoring : JEM.

[258] Jost O.L. Wendt,et al. Trace metal transformation mechanisms during coal combustion , 1994 .

[259] J. Helble,et al. Reaction of arsenic vapor species with fly ash compounds: kinetics and speciation of the reaction with calcium silicates. , 2003, Chemosphere.

[260] H. Bem,et al. Evaluation of technologically enhanced natural radiation near the coal-fired power plants in the Lodz region of Poland. , 2002, Journal of environmental radioactivity.

[261] James F. Meagher,et al. The evolution of photochemical smog in a power plant plume , 1999 .

[262] Deyi Wu,et al. Changes of mineralogical–chemical composition, cation exchange capacity, and phosphate immobilization capacity during the hydrothermal conversion process of coal fly ash into zeolite , 2008 .

[263] Ersoy Taşdemiroğlu. Environmental damage due to thermal power generation in Türkiye , 1994 .

[264] M. Eisenbud,et al. Radioactivity in the Atmospheric Effluents of Power Plants That Use Fossil Fuels , 1964, Science.

[265] M. Hardy. Effects of coal fly-ash disposal on water quality in and around the Indiana Dunes National Lakeshore, Indiana , 1981 .

[266] T. Anderson,et al. Sulfur isotopic variations in low-sulfur coals from the Rocky Mountain region , 1986 .

[267] Hoseyn Sayyaadi,et al. Comprehensive exergetic and economic comparison of PWR and hybrid fossil fuel-PWR power plants , 2010 .

[268] Md. Rafiqul Islam,et al. Mining-induced fault reactivation associated with the main conveyor belt roadway and safety of the Barapukuria Coal Mine in Bangladesh: Constraints from BEM simulations , 2009 .

[269] J. M. Wheeldon,et al. Preliminary results of an engineering and economic evaluation of Lurgi-Lentjes-Babcock`s circulating PFBC power plant design , 1996 .

[270] Wayne Seames,et al. An initial study of the fine fragmentation fly ash particle mode generated during pulverized coal combustion , 2003 .

[271] Myoung Kim,et al. Design and Feasibility Assessment of a Retrospective Epidemiological Study of Coal-Fired Power Plant Emissions in the Pittsburgh Pennsylvania Region , 2006 .

[272] Hongliang Yang,et al. Incorporating Both Undesirable Outputs and Uncontrollable Variables into Dea: the Performance of Chinese Coal-fired Power Plants Incorporating Both Undesirable Outputs and Uncontrollable Variables into Dea: the Performance of Chinese Coal-fired Power Plants , 2007 .

[273] J. Hower,et al. Petrography and chemistry of fly ash from the Shawnee Power Station, Kentucky , 1994 .

[274] R. Harley,et al. Mercury Balance on a Large Pulverized Coal-Fired Furnace , 1973 .

[275] D. Spears,et al. The determination of low level trace elements in coals by laser ablation-inductively coupled plasma-mass spectrometry , 1999 .

[276] Kevin R. Smith,et al. Particle characteristics responsible for effects on human lung epithelial cells. , 2002, Research report.

[277] Katherine L. Smith,et al. Chemical composition of fuels and emissions from a coal + tire combustion experiment in a power station , 2006 .

[278] J. Milford,et al. After the clean air mercury rule: prospects for reducing mercury emissions from coal-fired power plants. , 2009, Environmental science & technology.

[279] T. R. Carey,et al. Factors Affecting Mercury Control in Utility Flue Gas Using Activated Carbon. , 1998, Journal of the Air & Waste Management Association.

[280] RajenderKumar Gupta,et al. Oxy-fuel combustion technology for coal-fired power generation , 2005 .

[281] A. L. Page,et al. Physical and chemical properties of fly ash from coal-fired power plants with reference to environmental impacts , 1979 .

[282] W. Zoller,et al. Single-particle analysis of the ash from the Dickerson coal-fired power plant , 1977 .

[283] Z. Matyniak. Contribution of SO2 sorption on particulate surface to the air pollution level in the vicinity of coal-fired power plants. , 1989, The Science of the total environment.

[284] Norbert Berkowitz,et al. An introduction to coal technology , 1979 .

[285] David V. Bubenick. Economic Comparison of Selected Scenarios for Electrostatic Precipitators and Fabric Filters , 1978 .

[286] Pavel Slavik,et al. Dynamic models of the lignite transport in dryer of power plant boiler , 1999 .

[287] W. Conner,et al. Predicting the visibility of chimney plumes: An intercomparison of four models with observations at a well-controlled power plant , 1985 .

[288] J. Whelan,et al. Stable isotope geochemistry of sphalerite and other mineral matter in coal beds of the Illinois and Forest City basins , 1988 .

[289] Kuang-Yu Liu,et al. Filtration of fly ash using fluidized bed at 300–500 °C , 2007 .

[290] Hao Jianzhong,et al. Preliminary research of health and environmental impacts and greenhouse gas emission from coal-fired power and nuclear power chains in China , 1999 .

[291] C. Carlson,et al. Growth and elemental content of two tree species growing on abandoned coal fly ash basins. [Liquidambar styraciflua L. ; Platanus occidentalis] , 1991 .

[292] J. Amonette,et al. Comparing metal leaching and toxicity from high pH, low pH, and high ammonia fly ash , 2007 .

[293] Airey. Contributions from coal and industrial materials to mercury in air, rainwater and snow. , 1982, The Science of the total environment.

[294] J. Harris,et al. Seasonal cycle and composition of background fine particles along the west coast of the US , 2005 .

[295] B. J. Presley,et al. Mercury and Other Trace Elements in Sediment Cores from Central Texas Lakes , 2003, Archives of environmental contamination and toxicology.

[296] Amornvadee Veawab,et al. Integration of CO2 capture unit using single- and blended-amines into supercritical coal-fired power plants: Implications for emission and energy management , 2007 .

[297] Edward S. Rubin,et al. Evaluating Trace Chemical Emissions from Electric Power Plants , 1996 .

[298] J. Ondov,et al. Chemical studies of stack fly ash from a coal-fired power plant , 1979 .

[299] W. Abel,et al. Dry Separation of Pyrite from Coal , 1972 .

[300] R. Hatt. Fireside deposits in coal-fired utility boilers , 1990 .

[301] Steven A. Benson,et al. A comprehensive slagging and fouling prediction tool for coal-fired boilers and its validation/application , 2007 .

[302] Steven A. Benson,et al. SCR catalyst performance in flue gases derived from subbituminous and lignite coals , 2005 .

[303] S. Vassilev,et al. Methods for Characterization of Composition of Fly Ashes from Coal-Fired Power Stations: A Critical Overview , 2005 .

[304] B. Jobson,et al. Emissions lifetimes and ozone formation in power plant plumes , 1998 .

[305] E. Rubin,et al. A Probabilistic Emissions Model for Managing Hazardous Air Pollutants , 1991 .

[306] G. Gebhardt. Steam Power Plant Engineering , 2010 .

[307] A. M. Godridge,et al. Combustion and heat transfer in large boiler furnaces , 1976 .

[308] J. Surrey. Electric power plant in India: a strategy of self-reliance , 1987 .

[309] A. Furr,et al. National survey of elements and radioactivity in fly ashes. Absorption of elements by cabbage grown in fly ash-soil mixtures , 1977 .

[310] B. R. Pease,et al. Pilot scale study of trace element vaporization and condensation during combustion of a pulverized sub-bituminous coal , 2000 .

[311] S. Vassilev,et al. Phase-mineral and chemical composition of coal fly ashes as a basis for their multicomponent utilization. 1. Characterization of feed coals and fly ashes☆ , 2003 .

[312] S. E. Simopoulos,et al. Natural radioactivity releases from lignite power plants in Greece , 1987 .

[313] Jiming Hao,et al. Primary air pollutant emissions of coal-fired power plants in China: Current status and future prediction , 2008 .

[314] Volker Rose,et al. High-resolution nanoprobe X-ray fluorescence characterization of heterogeneous calcium and heavy metal distributions in alkali-activated fly ash. , 2009, Langmuir : the ACS journal of surfaces and colloids.

[315] R. Zaharchuk,et al. Assessment of hot particulate removal systems for IGCC and PFBC advanced power systems , 1996 .

[316] Steven R. Hanna,et al. Predicted and observed cooling tower plume rise and visible plume length at the John E. Amos power plant , 1976 .

[317] Mark L. Johnson,et al. Preventing mercury emissions from coal-fired power plants using environmentally preferable coal purchasing practices , 2008 .

[318] J. Hower,et al. Chemistry of coal and coal combustion products from Kentucky power plants: Results from the 2007 sampling, with emphasis on selenium , 2009 .

[319] Studies of carbonaceous cenospheres from fluidised-bed combustors , 1984 .

[320] V. Havranek,et al. Influence of Calcareous Sorbents on Particulate Emissions from Fluidized Bed Combustion of Lignite , 2000 .

[321] W. Parkhurst,et al. Rates of Conversion of Sulfur Dioxide to Sulfate in a Scrubbed Power Plant Plume , 2001, Journal of the Air & Waste Management Association.

[322] L. Husain,et al. Identification of submicrometer coal fly ash in a high-sulfate episode at Whiteface Mountain, New York , 1985 .

[323] K. Felsvang,et al. Activated carbon injection in spray dryer/ESP/FF for mercury and toxics control , 1994 .

[324] M. Flues,et al. The influence of a coal-fired power plant operation on radionuclide concentrations in soil. , 2002, Journal of environmental radioactivity.

[325] P. C van der Laag,et al. Prospects for advanced coal-fuelled fuel cell power plants , 1994 .

[326] Guijian Liu,et al. Petrological and mineralogical characterizations and chemical composition of coal ashes from power plants in Yanzhou mining district, China , 2004 .

[327] Haiqing Lin,et al. Power plant post-combustion carbon dioxide capture: An opportunity for membranes , 2010 .

[328] R. Meij,et al. The Fate and Behavior of Mercury in Coal-Fired Power Plants , 2002, Journal of the Air & Waste Management Association.

[329] Stephen L. Feldman,et al. Impact of pollution controls on the productivity of coal-fired power plants , 1990 .

[330] J. Ondov,et al. Elemental emissions from a coal-fired power plant. Comparison of a Venturi wet scrubber system with a cold-side electrostatic precipitator. , 1979, Environmental science & technology.

[331] W. Cope,et al. Does proximity to coal-fired power plants influence fish tissue mercury? , 2010, Ecotoxicology.

[332] Noam Lior,et al. A numerical analysis of NOx formation and control in radiatively/ conductively-stabilized pulverized coal combustors , 1998 .

[333] James E. Staudt,et al. SCR Catalyst Management Strategies - Modeling and Experience , 2003 .

[334] S. Vassilev,et al. Behaviour of elements and minerals during preparation and combustion of the Pernik coal, Bulgaria , 2001 .

[335] T. Wheelock,et al. Process Conditions for the Separation of Carbon from Fly Ash by Froth Flotation , 2008 .

[336] Phillip L. Williams,et al. Occupational Exposures During Routine Activities in Coal-Fueled Power Plants , 2004, Journal of Occupational and Environmental Hygiene.

[337] F. Huggins,et al. Environmental assessment of elements and polyaromatic hydrocarbons emitted from a Canadian coal-fired power plant , 2009 .

[338] Kathryn G. Zeiler,et al. The use of microalgae for assimilation and utilization of carbon dioxide from fossil fuel-fired powe , 1995 .

[339] R. N. Kar,et al. Effect of chemical pretreatment on bacterial desulphurisation of Assam coal , 1998 .

[340] Lin Ma,et al. Prediction of unburned carbon and NOx in a tangentially fired power station using single coals and blends , 2005 .

[341] W. Sage,et al. Relationship of Coal-Ash Viscosity to Chemical Composition , 1960 .

[342] Nurdil Eskin,et al. Effects of operational parameters on the thermodynamic performance of FBCC steam power plant , 2009 .

[343] Loss rate of NO y from a power plant plume based on aircraft measurements , 1998 .

[344] G. Fryxell,et al. Removal of Mercury from Aqueous Streams of Fossil Fuel Power Plants Using Novel Functionalized Nanoporous Sorbents , 2006 .

[345] H. Cohen,et al. Neutralization of acid mine drainage by Turkish lignitic fly ashes; role of organic additives in the fixation of toxic elements , 2002 .

[346] M. Hicks,et al. Airborne Exposure to Arsenic Occurring in Coal Fly Ash , 1999 .

[347] D. A. Conner,et al. Power plant siting , 1978 .

[348] D. Ensor,et al. Critical Review: Measurement of Mercury Combustion Aerosols in Emissions From Stationary Sources , 1986 .

[349] Howard J. Herzog,et al. Capture-ready coal plants—Options, technologies and economics , 2007 .

[350] K. J. Reddy. Coal Fly Ash Chemistry and Carbon Dioxide Infusion Process to Enhance its Utilization , 1999 .

[351] Mary Stewart,et al. Multi‐Criteria Decision Analysis: The Case of Power Generation in South Africa , 2005 .

[352] MA Zhuang-wei,et al. The estimation of mercury emission from coal combustion in China. , 2000 .

[353] Esko I. Kauppinen,et al. Coal combustion aerosols: a field study , 1990 .

[354] R. Finkelman,et al. The types of data needed for assessing the environmental and human health impacts of coal , 1999 .

[355] S. Pandey. Impact of thermal power plant emissions on vegetation and soil , 1983 .

[356] J. J. O'Toole,et al. Growth responses of selected freshwater algae to trace elements and scrubber ash slurry generated by coal-fired power plants , 1980 .

[357] B. K. Dutta,et al. Leaching of elements from coal fly ash: Assessment of its potential for use in filling abandoned coal mines , 2009 .

[358] R. Cahill,et al. Survey of trace elements in coals and coal-related materials by neutron activation analysis , 1977 .

[359] S. Prakash,et al. Performance of Al2O3-3%TiO2 Detonation gun coated ferritic steels in coal fired boiler , 2009 .

[360] J. Hower,et al. Sulfur and carbon isotope geochemistry of coal and derived coal-combustion by-products : An example from an Eastern Kentucky mine and power plant , 2007 .

[361] P. Noskievic,et al. Quality of combustion processes -- An assessment , 1996 .

[362] J. Hower,et al. Coal combustion by-product quality at two stoker boilers: Coal source vs. fly ash collection system design , 2008 .

[363] R. Colvile,et al. Dispersion of As and selected heavy metals around a coal-burning power station in central Slovakia. , 2006, The Science of the total environment.

[364] Sharma,et al. Catalytic effects of carbon sorbents for mercury capture , 2000, Journal of hazardous materials.

[365] F. Huggins,et al. Speciation of nickel in Canadian subbituminous and bituminous feed coals, and their ash by-products. , 2004, Journal of environmental monitoring : JEM.

[366] D. Akers,et al. Role of coal cleaning in control of air toxics , 1994 .

[367] V. Prybutok. Sensitivity analysis for power industry radionuclide air stack emissions leukemia incidence risk comparison models , 1991 .

[368] S. P. Taneja. Mössbauer Studies of Thermal Power Plant Coal and Fly Ash , 2004 .

[369] J. Osán,et al. Quantitative trace element analysis of individual fly ash particles by means of X-ray microfluorescence. , 2002, Analytical chemistry.

[370] Prakash Karamchandani,et al. Global source attribution for mercury deposition in the United States. , 2004, Environmental science & technology.

[371] Edward S. Rubin,et al. Modeling of integrated environmental control systems for coal-fired power plants , 1988 .

[372] N. Öztürk,et al. Preliminary analyses of natural radionuclides in selected Turkish power plant lignites , 2004 .

[373] A. Wexler,et al. The occurrence of sulfuric acid‐water nucleation in plumes: urban environment , 1996 .

[374] H. J. Wouterlood,et al. Removal and recovery of arsenious oxide from flue gases , 1979 .

[375] Jian Zhang,et al. Simulation of gas-particle turbulent combustion in a pulverized coal-fired swirl combustor , 2009 .

[376] S. Mendioroz,et al. Mercury elimination from gaseous streams , 1993 .

[377] Lingqing Wang,et al. Spatial distribution and risk assessment of radionuclides in soils around a coal-fired power plant: a case study from the city of Baoji, China. , 2007, Environmental research.

[378] K. Arai,et al. Trial design for a CO2 recovery power plant by burning pulverized coal in , 1997 .

[379] R. Meij. The Distribution of Trace Elements During the Combustion of Coal , 1995 .

[380] S. Niksa,et al. A Mechanism for Mercury Oxidation in Coal-Derived Exhausts , 2002, Journal of the Air & Waste Management Association.

[381] A. R. Ramsden,et al. Some microscopic features of fly-ash particles and their significance in relation to electrostatic precipitation , 1970 .

[382] R. Hurst,et al. Strontium isotopes as tracers of airborne fly ash from coal-fired power plants , 1981 .

[383] M Granger Morgan. Don't Grandfather Coal Plants , 2006, Science.

[384] S. Vassilev,et al. A new approach for the classification of coal fly ashes based on their origin, composition, properties, and behaviour , 2007 .

[385] R. Shia,et al. Multiscale modeling of the atmospheric fate and transport of mercury , 2001 .

[386] Domy C. Adriano,et al. Environmental impacts of coal combustion residues , 1993 .

[387] V. I. Kouprianov,et al. Optimization of excess air for the improvement of environmental performance of a 150 MW boiler fired with Thai lignite , 2003 .

[388] A. Myrick Freeman,et al. Estimating the environmental costs of electricity: An overview and review of the issues , 1996 .

[389] Antonio Valero,et al. Ash fouling in coal-fired utility boilers. Monitoring and optimization of on-load cleaning , 1996 .

[390] J. Garty,et al. Heavy metals in the lichen Ramalina duriaei transplanted at biomonitoring stations in the region of a coal-fired power plant in Israel after 3 years of operation , 1988, Water, Air, and Soil Pollution.

[391] Gerard V. Smith,et al. Mössbauer studies of iron in Lurgi gasification ashes and power plant fly and bottom ash , 1980 .

[392] Malvina Baica,et al. Regarding the relation between the NOx content and CO content in thermo power plants flue gases , 2005 .

[393] J. A. Ratafia-brown. Overview of trace element partitioning in flames and furnaces of utility coal-fired boilers , 1994 .

[394] E. Edgerton,et al. Characterization and cycling of atmospheric mercury along the central US Gulf Coast , 2008 .

[395] Nenad Sarunac,et al. USE OF COAL DRYING TO REDUCE WATER CONSUMED IN PULVERIZED COAL POWER PLANTS , 2004 .

[396] James Stewart,et al. Utilization of Illinois PCC Dry Bottom Ash for Compacted Landfill Barriers , 2003 .

[397] J. L. Wong,et al. Chromium valence forms of coal fly ash in the solid state and leachates , 1996 .

[398] C. Warren,et al. Submicroscopic model of fly ash particles , 1987 .

[399] Ravi K Srivastava,et al. Nitrogen Oxides Emission Control Options for Coal-Fired Electric Utility Boilers , 2005, Journal of the Air & Waste Management Association.

[400] F. Kastner,et al. Zum Verhalten des Spurenelementes Quecksilber in Steinkohlefeuerungen mit Rauchgasreinigungsanlagen , 1992 .

[401] Wei Sun,et al. Application of impression creep data in life assessment of power plant materials at high temperatures , 2008 .

[402] J. Hower,et al. Variations in fly ash composition with sampling location: Case study from a portuguese power plant , 2009 .

[403] T. Keener,et al. Bench-scale studies of in-duct mercury capture using cupric chloride-impregnated carbons. , 2009, Environmental science & technology.

[404] Paul Feron,et al. Exploring the potential for improvement of the energy performance of coal fired power plants with post-combustion capture of carbon dioxide , 2010 .

[405] F. Harrison,et al. Comparison of organic combustion products in fly ash collected by a Venturi wet scrubber and an electrostatic precipitator at a coal-fired power station , 1985 .

[406] Rick Honaker,et al. Paste Thickening of Fine Coal Refuse , 2007 .

[407] R. Bordia,et al. Transactions of the American Nuclear Society , 2012 .

[408] Williams,et al. Plume Blight Visibility Modeling with A Simulated Photograph Technique , 1979 .

[409] Gheorghe Popescu,et al. New approach to thermal power plants operation regimes maximum power versus maximum efficiency , 2007 .

[410] A Model of Environmental Transport of Heavy Metals Originating From Stack Derived Particulate Emission in Semi-Arid Regions , 1977 .

[411] R. Kikuchi. The Possibility of Combining Solutions to Air Pollution with Policies for Social Improvement through Transformation of SOx and NOx into Fertilizer: Data Obtained from the Szechwan Project , 2004 .

[412] H. Sanei,et al. Assessment of elements, speciation of As, Cr, Ni and emitted Hg for a Canadian power plant burning bituminous coal , 2008 .

[413] P. Stocks. Recent epidemiological studies of lung cancer mortality cigarette smoking and air pollution, with discussion of a new hypothesis of causation. , 1966, British Journal of Cancer.

[414] E. Angino,et al. Leaching characteristics of a high-calcium fly ash as a function of pH: a potential source of selenium toxicity , 1988 .

[415] Lucie Bartoňová,et al. Effect of boiler output on trace element partitioning during coal combustion in two fluidised-bed power stations , 2001 .

[416] R. M. Goldstein,et al. A Biologist's manual for the evaluation of impacts of coal-fired power plants on fish, wildlife, and their habitats , 1978 .

[417] C. P. Bergmann,et al. Optimizing Coal Feed in a Brazilian Thermal Power Plant: A Case Study , 2004 .

[418] F. Gera,et al. Utilization of ASH and Gypsum Produced by Coal Burning Power Plants , 1991 .

[419] D. W. Pershing,et al. Fate of coal nitrogen during combustion , 1982 .

[420] B. Valentim,et al. Characterization of fly ash from a power plant and surroundings by micro-Raman spectroscopy , 2008 .

[421] Luis M. Romeo,et al. Economical assessment of competitive enhanced limestones for CO2 capture cycles in power plants , 2009 .

[422] R. E. Lee,et al. Concentration and size of trace metal emissions from a power plant, a steel plant, and a cotton gin , 1975 .

[423] Anna Nagurney,et al. Optimal endogenous carbon taxes for electric power supply chains with power plants , 2006, Math. Comput. Model..

[424] Joel Martinez-Frias,et al. Thermodynamic Analysis of Zero-Atmospheric Emissions Power Plant , 2004 .

[425] U. C. Mishra,et al. Radioactivity release to the environment by thermal power stations using coal as a fuel , 1980 .

[426] D. Schindler,et al. Impacts of Coal-Fired Power Plants on Trace Metals and Polycyclic Aromatic Hydrocarbons (PAHs) in Lake Sediments in Central Alberta, Canada , 2006 .

[427] Song Hu,et al. An experimental research on boiler combustion performance , 2000 .

[428] G. Silcox,et al. Adsorption of Elemental Mercury on the Residual Carbon in Coal Fly Ash , 2000 .

[429] Terry Wall,et al. Computer-controlled scanning electron microscopy of minerals in coal—Implications for ash deposition , 1998 .

[430] C. W. Bailey,et al. Investigation of the High-Temperature Behavior of Excluded Siderite Grains during Pulverized Fuel Combustion , 1998 .

[431] M. Germani,et al. Vapor-phase concentrations of arsenic, selenium, bromine, iodine, and mercury in the stack of a coal-fired power plant. , 1988, Environmental science & technology.

[432] F. Zhao,et al. Comparative leaching experiments for trace elements in raw coal, laboratory ash, fly ash and bottom ash , 1999 .

[433] M. Mastalerz,et al. From in-situ coal to fly ash: a study of coal mines and power plants from Indiana , 2004 .

[434] R. Prasad,et al. Enhancement of trace uranium in fly ash , 1994 .

[435] T. R. Carey,et al. Development of carbon-based adsorbents for removal of mercury emissions from coal combustion flue gas , 1999 .

[436] M. Hupa,et al. The effects of pressure, oxygen partial pressure, and temperature on the formation of N2O, NO, and NO2 from pulverized coal , 1995 .

[437] E. Larson,et al. A high-resolution emission inventory for eastern China in 2000 and three scenarios for 2020 , 2005 .

[438] C. Seigneur,et al. Simulation of Stack Plume Opacity , 2000, Journal of the Air & Waste Management Association.

[439] Adam Rose,et al. Clean Coal Technologies and Future Prospects for Coal , 1991 .

[440] Jianmin Wang,et al. Characterizing the metal adsorption capability of a class F coal fly ash. , 2004, Environmental science & technology.

[441] George A. Farthing,et al. Development of Mercury Emissions Control Technologies for the Power Industry , 1999 .

[442] T. Bakharev,et al. Thermal behaviour of geopolymers prepared using class F fly ash and elevated temperature curing , 2006 .

[443] P. Arlien‐Søborg,et al. Science of the Total Environment , 2018 .

[444] S. W. Lee. Fine particulate matter measurement and international standardization for air quality and emissions from stationary sources , 2010 .

[445] E. Edgerton,et al. Mercury speciation in coal-fired power plant plumes observed at three surface sites in the southeastern U.S. , 2006, Environmental science & technology.

[446] J. Smith,et al. The stable isotope geochemistry of Australian coals , 1981 .

[447] F. Goodarzi,et al. Parameters influencing the variation in mercury emissions from an Alberta power plant burning high inertinite coal over thirty-eight weeks period , 2006 .

[448] W. Roy,et al. A Proposed Classification System for Coal Fly Ash in Multidisciplinary Research , 1982 .

[449] John Davison,et al. Performance and costs of power plants with capture and storage of CO2 , 2007 .

[450] Junying Zhang,et al. Mineralogy and microstructure of ash deposits from the Zhuzhou coal-fired power plant in China , 2010 .

[451] K. Okazaki,et al. Simultaneous easy CO2 recovery and drastic reduction of SOx and NOx in O2/CO2 coal combustion with heat recirculation☆ , 2003 .

[452] Jon P. Rezek,et al. Cost estimates for multiple pollutants: A maximum entropy approach , 2007 .

[453] M. Izquierdo,et al. Coal fly ash based carbons for SO2 removal from flue gases. , 2010, Waste management.

[454] J. Costa,et al. Isolation and selection of microalgae from coal fired thermoelectric power plant for biofixation of carbon dioxide , 2007 .

[455] J. Hower. Maceral/ microlithotype partitioning with particle size of pulverized coal: Examples from power plants burning Central Appalachian and Illinois basin coals , 2008 .

[456] J. Blažek,et al. Composition and morphology of stack emissions from coal and oil fuelled boilers , 1989 .

[457] Zhenghe Xu,et al. Potential of Air Dense Medium Fluidized Bed Separation of Mineral Matter for Mercury Rejection from Alberta Sub-Bituminous Coal , 2008 .

[458] Matthew E. Kahn. Regional growth and exposure to nearby coal fired power plant emissions , 2009 .

[459] Takahisa Yokoyama,et al. Emissions of mercury and other trace elements from coal-fired power plants in Japan. , 2006, The Science of the total environment.

[460] R. R. Hardman,et al. Computer modeling of the coal combustion process to quantify the impacts of burner balancing on NOx emissions and other boiler performance indicators , 1996 .

[461] Robert W. Keating,et al. Maryland Power Plant Research Program Promotes the Beneficial Use of CCPs as a Means to Protect Maryland's Natural Resources , 1999 .

[462] Manoj K. Mohanty,et al. Techno-Economic Analysis of Coal Preparation Plant Design Using Siu-Sim Simulator , 2008 .

[463] B. Gloebel,et al. Investigations on fly-ash and soil samples in the environment of a coal-fired power plant. , 1985, The Science of the total environment.

[464] R. I. Hook. Potential health and environmental effects of trace elements and radionuclides from increased coal utilization. , 1979 .

[465] M. Seggiani. Empirical correlations of the ash fusion temperatures and temperature of critical viscosity for coal and biomass ashes , 1999 .

[466] R. R. McKinsey,et al. Repowering an existing utility power plant with a circulating PFBC boiler , 1996 .

[467] Xavier Querol,et al. Characterization of Candiota (South Brazil) coal and combustion by-product , 2004 .

[468] X. Querol,et al. Extraction of soluble major and trace elements from fly ash in open and closed leaching systems , 2001 .

[469] Winston Chow,et al. Managing Hazardous Air Pollutants: State of the Art , 1993 .

[470] P. M. Hamilton,et al. Observations of Power Station Plumes using a Pulsed Ruby Laser Rangefinder , 1966, Nature.

[471] W. R. Kube,et al. Technology and use of lignite , 1974 .

[472] Sharon Sjostrom,et al. Assessing Sorbents for Mercury Control in Coal-Combustion Flue Gas , 2002, Journal of the Air & Waste Management Association.

[473] Asok Ray,et al. Life-extending control of fossil fuel power plants , 1997, Autom..

[474] L. H. Weinstein,et al. A review of physical, chemical, and biological properties of fly ash and effects on agricultural ecosystems. , 1988, The Science of the total environment.

[475] D. Sengupta,et al. Natural radioactivity of ash and coal in major thermal power plants of West Bengal, India , 2006 .

[476] C. Sabbioni,et al. Morphology and mineralogy of fly ash from a coal-fueled power plant , 1984 .

[477] S. Durrani,et al. An investigation of radon exhalation from fly ash produced in the combustion of coal , 1988 .

[478] Y. Shieh,et al. The distribution and isotopic composition of sulfur in coals from the Illinois Basin , 1979 .

[479] J. Speight,et al. Chemistry and technology of coal , 2012 .

[480] P. Borm,et al. Toxicity and occupational health hazards of coal fly ash (CFA). A review of data and comparison to coal mine dust. , 1997, The Annals of occupational hygiene.

[481] H. Eaton,et al. 57Fe Mössbauer spectroscopic studies of fly ash from coal-fired power plants and bottom ash from lignite-natural gas combustion , 1984 .

[482] S. Audebert,et al. A comprehensive theoretical, numerical and experimental approach for crack detection in power plant rotating machinery , 2008 .

[483] Min Liu,et al. [Estimate the mercury emissions from non-coal sources in China]. , 2006, Huan jing ke xue= Huanjing kexue.

[484] James Stewart,et al. Strength characteristics of illinois coal combustion by‐product: PCC dry bottom ash , 2004 .

[485] Prinya Chindaprasirt,et al. Utilization of blended fluidized bed combustion (FBC) ash and pulverized coal combustion (PCC) fly ash in geopolymer. , 2010, Waste management.

[486] Norma Amadeo,et al. Assessment of CO2 capture and storage from thermal power plants in Argentina , 2005 .

[487] Yong-Chil Seo,et al. Speciation and mass distribution of mercury in a bituminous coal-fired power plant , 2006 .

[488] R. Mann,et al. Trace Element Emissions from Coal-Fired Power Plants , 1979 .

[489] James Petrie,et al. Inventory and Impact Assessment Uncertainty in Coal-Based Power Generation , 2005 .

[490] B. Scarlett,et al. Removal of heavy metals from fly ash and the impact on its quality , 2002 .

[491] Giovanni Lozza,et al. Long-term coal gasification-based power plants with near-zero emissions. Part A: Zecomix cycle , 2010 .

[492] M. P. Ketris,et al. Mercury in coal: a review: Part 1. Geochemistry , 2005 .

[493] P. E. Chew. PF-fired supercritical power plant , 2003 .

[494] Howard J. Herzog,et al. Optimization of carbon capture percentage for technical and economic impact of near-term CCS implementation at coal-fired power plants , 2009 .

[495] B. Tomkins,et al. Improved ultrasonic extraction recovery of benzo(a)pyrene from stack ash using high power/mass ratios , 1988 .

[496] A. Robinson,et al. Effects of Sampling Conditions on the Size Distribution of Fine Particulate Matter Emitted from a Pilot-Scale Pulverized-Coal Combustor , 2002 .

[497] S. Ito,et al. Mercury oxidation by copper oxides in combustion flue gases , 2008 .

[498] Harold J. Annegarn,et al. The spontaneous combustion of coal and its by-products in the Witbank and Sasolburg coalfields of South Africa , 2007 .

[499] U. C. Mishra,et al. Environmental impact of coal industry and thermal power plants in India. , 2004, Journal of environmental radioactivity.

[500] A. Andren,et al. Mass balance of trace elements in Walker branch watershed: relation to coal-fired steam plants. , 1975, Environmental health perspectives.

[501] A. M. Al Taweel,et al. Impact of coal quality on the cost of electrical power generation: A technoeconomic model , 1990 .

[502] I. Twardowska. Environmental Aspects of Power Plants Fly Ash Utilization in Deep Coal Mine Workings , 1999 .

[503] S. Vassilev,et al. Low cost catalytic sorbents for NOx reduction. 3. NO reduction tests using NH3 as reducing agent , 2004 .

[504] Sudesh Chaudhary,et al. Speciation of some heavy metals in coal fly ash , 2007 .

[505] Stefan Vögele,et al. Environmental impacts of a German CCS strategy , 2009 .

[506] John S. Nordin,et al. NOx EMISSIONS PRODUCED WITH COMBUSTION OF POWDER RIVER BASIN COAL IN A UTILITY BOILER , 1997 .

[507] J. Ondov,et al. Elemental composition of atmospheric fine-particles emitted from coal burned in a modern electric power plant equipped with a flue-gas desulfurization system , 1981 .

[508] Lars Håkanson,et al. Mercury in the Swedish environment — Recent research on causes, consequences and corrective methods , 1991 .

[509] R. Pueschel. Aerosol formation during coal combustion: Condensation of sulfates and chlorides on flyash , 1976 .

[510] Lester B. Lave,et al. Health effects of electricity generation from coal, oil, and nuclear fuel , 1973 .

[511] H. T. Morehead,et al. Major enhancement to the competitiveness of Foster Wheeler`s topping PCFB , 1996 .

[512] M. Isreb,et al. Superheater minimum stress unit start-up option of coal-fired power plant , 1997 .

[513] S. Nakayama,et al. Pulverized coal combustion in O2/CO2 mixtures on a power plant for CO2 recovery , 1992 .

[514] Griffis Lc,et al. Clearance by the rat of inhaled fly ash from fluidized-bed coal combustion , 1981 .

[515] J. Meagher,et al. The Atmospheric Oxidation of Flue Gases from a Coal-Fired Power Plant: A Comparison between Smog Chamber and Airborne Plume Sampling , 1983 .

[516] U. C. Mishra,et al. Modifications in natural radioactivity content of soil samples around thermal power stations in India , 1990 .

[517] P. Froelich,et al. Tracing Germanium Contamination from Coal-fired Power Plants Down the Chattahoochee-Apalachicola System: Implications for the Toxic Metalloids Arsenic and Selenium , 2001 .

[518] C. Crocker,et al. Application of sorbents for mercury control for utilities burning lignite coal , 2004 .

[519] Mingyao Zhang,et al. NOx emissions of an opposed wall-fired pulverized coal utility boiler , 2009 .

[520] L. Hulett,et al. Some etching studies of the microstructure and composition of large aluminosilicate particles in fly ash from coal-burning power plants. , 1980, Environmental Science and Technology.

[521] P. Ausset,et al. Physico-Chemical Characterization and Leaching of Desulphurization Coal Fly Ash , 1996 .

[522] J. Vazquez,et al. Characterization of Polycyclic Aromatic Hydrocarbons in Emissions from Coal-Fired Power Plants: The Influence of Operation Parameters , 1999 .

[523] T. D. Brown,et al. Impact of Flue Gas Conditions on Mercury Uptake by Sulfur-Impregnated Activated Carbon , 2000 .

[524] R. E. Gray,et al. Fluid placement of fixated scrubber sludge to reduce surface subsidence and to abate acid mine drainage in abandoned underground coal mines , 1995 .

[525] Teresa Moreno,et al. The identification of metallic elements in airborne particulate matter derived from fossil fuels at Puertollano, Spain , 2007 .

[526] Yasuo Suzuoki,et al. Effective utilization of woody biomass for electricity production in Japan. -Comparative assessment of co-firing in coal fired power plant and fuel cell with gasification- , 2005 .

[527] T. Praharaj,et al. Geochemical studies to delineate topsoil contamination around an ash pond of a coal-based thermal power plant in India , 2003 .

[528] William F. Fitzgerald,et al. The Case for Atmospheric Mercury Contamination in Remote Areas , 1998 .

[529] Jan-Dirk Herbell,et al. Utilization of fly ash from coal-fired power plants in China , 2008 .

[530] C. A. Roberts,et al. Potential for improvement in power generation with post-combustion capture of CO2 , 2005 .

[531] R. Bryers,et al. Ash deposits and corrosion due to impurities in combustion gases , 1978 .

[532] Chiu-Yue Lin,et al. REMOVAL OF POLLUTANTS FROM WASTEWATER BY COAL BOTTOM ASH , 2002, Journal of environmental science and health. Part A, Toxic/hazardous substances & environmental engineering.

[533] TOXICOLOGICAL EVALUATION OF REALISTIC EMISSIONS OF SOURCE AEROSOLS (TERESA): APPLICATION TO POWER PLANT-DERIVED PM2.5 , 2004 .

[534] R. Tanner,et al. Influence of natural hydrocarbons on ozone formation in an isolated power plant plume , 2000 .

[535] P. Woodbury,et al. A Review of Selenium Uptake, Transformation, and Accumulation by Plants with Particular Reference to Coal Fly Ash Landfills , 1999 .

[536] J. Kelso,et al. Entrainment and Impingement of Fish by Power Plants in the Great Lakes which use the Once-Through Cooling Process , 1979 .

[537] Rick Honaker,et al. Picobubble Column Flotation of Fine Coal , 2008 .

[538] János M. Beér,et al. Combustion technology developments in power generation in response to environmental challenges , 2000 .

[539] Minghou Xu,et al. Physicochemical properties and potential health effects of nanoparticles from pulverized coal combustion , 2009 .

[540] Behdad Moghtaderi,et al. A computational fluid dynamics based study of the combustion characteristics of coal blends in pulverised coal-fired furnace , 2004 .

[541] S. Elevli,et al. Coal Quality Control with Control Charts , 2006 .

[542] C. Seigneur,et al. Modeling of Potential Power Plant Plume Impacts on Dallas-Fort Worth Visibility , 2000, Journal of the Air & Waste Management Association.

[543] Ulrich Buskies,et al. The efficiency of coal-fired combined-cycle powerplants , 1996 .

[544] A. Andren,et al. Selenium in coal-fired steam plant emissions , 1975 .