| 75 - 77 |
Development of a mechanistic model for prediction of emission of trace elements from coal-fired power giants
Senior CL |
| 79 - 92 |
Mode of occurrence of chromium in four US coals
Huggins FE, Shah N, Huffman GP, Kolker A, Crowley S, Palmer CA, Finkelman RB |
| 93 - 107 |
Interactions between vapor-phase mercury compounds and coal char in synthetic flue gas
Wu BC, Peterson TW, Shadman F, Senior CL, Morency JR, Huggins FE, Huffman GP |
| 109 - 124 |
Laboratory study of trace element vaporization from combustion of pulverized coal
Senior CL, Bool LE, Morency JR |
| 125 - 147 |
A model for the air emissions of trace metallic elements from coal combustors equipped with electrostatic precipitators
Helble JJ |
| 149 - 165 |
Pilot scale study of trace element vaporization and condensation during combustion of a pulverized sub-bituminous coal
Senior CL, Bool LE, Srinivasachar S, Pease BR, Porle K |
| 167 - 178 |
Mode of occurrence of arsenic in four US coals
Kolker A, Huggins FE, Palmer CA, Shah N, Crowley SS, Huffman GP, Finkelman RB |
| 179 - 196 |
Partitioning of arsenic, selenium, and cadmium during the combustion of Pittsburgh and Illinois #6 coals in a self-sustained combustor
Seames WS, Wendt JOL |
| 197 - 213 |
Gas-phase transformations of mercury in coal-fired power plants
Senior CL, Sarofim AF, Zeng TF, Helble JJ, Mamani-Paco R |
| 215 - 241 |
Distribution of trace elements in selected pulverized coals as a function of particle size and density
Senior CL, Zeng T, Che J, Ames MR, Sarofim AF, Olmez I, Huggins FE, Shah N, Huffman GP, Kolker A, Mroczkowski S, Palmer C, Finkelman R |
