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References
[1]
Senior C.L.,
et al
. Gas-phase transformations of mercury in coal-fired power
plants.
Fuel Processing Technology
, 68(3): 197-213, 2000.
[2] Carpi A. Mercury from combustion sources: A review of the chemical species
emitted and their transport in the atmosphere.
Water, Air and Soil Pollution
, 98:
241-254, 1997.
[3] Widmer N.C., West J. Thermochemical Study of Mercury Oxidation in Utility
Boiler Fuel Gases. 93rd Annual Meeting, Air&Waste Management Association,
Salt Lake City, Utah, 2000.
[4] Lee T.G. Hg Reactions in the presence of chlorine species: homogeneous gas
phase and heterogeneous gas-solid phase.
Journal of the Air & Waste
Management Association
, 52: 1316-1323, 2002.
[5] Dunham G.E., DeWall R.A., Senior C.L. Fixed-bed studies of the interactions
between mercury and coal combustion fly ash.
Fuel Processing Technology
,
82(2-3): 197-213, 2003.
[6] Sliger R.N., Kramlicha J.C., Marinov N.M. Towards the development of a
chemical kinetic model for the homogeneous oxidation of mercury by chlorine
species.
Fuel Processing Technology
, (65-66): 423-438, 2000.
[7] Niksa S. Kinetic modeling of homogeneous mercury oxidation: the importance of
NO and H
2
O in predicting oxidation in coal-derived system.
Environmental
Science & Technology
,
35: 3701-3706, 2001.
[8] Liu J., Wand M.H., Zheng C.G.,
et al.
Reaction mechanism of mercury and gases
during coal combustion.
Journal of Engineering Thermophysics
, 24(1): 161-164,
2003.
[9] Mamani-Paco R.M., Helble J.J. Bench-Scale Examination of Mercury Oxidation
under Non-Isothermal Conditions. 93rd Annual Meeting & Exhibition, Air &
Waste Management Association, Salt Lake City, Utah, June 18-22, 2000.
[10] Dajnak D., Lockwood F.C. Modelling of toxic heavy metal mercury partitioning
from pulverized fuel combustion.
IFRF Combustion Journal
, Article Number
200103, 2001.
[11] Hall B., Schager P., Lindqvist O. Chemical reactions of mercury in combustion
flue gases.
Water, Air & Soil Pollution
, 56: 3-14, 1991.
[12] Matsumura Y. Adsorption of mercury vapor on the surface of activated carbons
modified by oxidation or iodization.
Atmospheric Environment
, 8: 1321-1327,
1974.
[13] Senior C.L., Morency J.R. Prediction of Mercury Speciation in Coal-Fired Power
Plant Flue Gas: A Fundamental Study. Managing Hazardous Air Pollutants,
Fourth International Conference, Washington, DC, November 12-14, 1997.
[14] Schager P. The Behavior of Mercury in Flue Gases. Department of Inorganic
Chemistry, University of Goteburg, Goteburg, Sweden, 1990.
[15] Liu Y.H. The Migration of Trace Elements in Coal Combustion Process Changes
in Behavior. Huazhong University of Science and Technology, 2002.
[16] Ren J.L. Experimental and Theoretical Study on Mercury Transformation and
Sorbents Adsorption in Simulated Combustion Flue Gases. College of
Mechanical and Energy Engineering, Zhejiang University, Hangzhou, 71-73.
2003.
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