參考文獻 |
Agarwalla, H., Senapati, R. N. & Das, T. B. (2021) Mercury emissions and partitioning
from Indian coal-fired power plants. Journal of Environmental Sciences 100, 28-
33.
ASTM (2016) Standard test method for elemental, oxidized, particle-bound and
mercury in flue gas generated from coal-fired stationary sources (Ontario hydro
method). World Trade Organization Technical Barriers to Total Trade (TBT)
Committee.
Bellanger, M., Pichery, C., Aerts, D., Berglund, M., Castaño, A., Čejchanová, M., &
Grandjean, P. (2013). Economic benefits of methylmercury exposure control in
Europe: monetary value of neurotoxicity prevention. Environmental Health, 12(1),
1-10.
Braune, B. M., Outridge, P. M., Fisk, A. T., Muir, D. C. G., Helm, P. A., Hobbs, K., &
Stirling, I. (2005). Persistent organic pollutants and mercury in marine biota of the
Canadian Arctic: an overview of spatial and temporal trends. Science of the Total
Environment, 351, 4-56.
Choi, H.K., Lee, S.H., Kim, S.S., 2009. The effect of activated carbon injection rate on
the removal of elemental mercury in a particulate collector with fabric filters. Fuel
Processing Technology 90 (1), 107–112.
Chou, C. P., Chang, T. C., Chiu, C. H., & Hsi, H. C. (2018). Mercury speciation and
mass distribution of cement production process in Taiwan. Aerosol and Air Quality
Research, 18(11), 2801-2812.
Chou, C. P., Chiu, C. H., Chang, T. C., & Hsi, H. C. (2021). Mercury speciation and
mass distribution of coal-fired power plants in Taiwan using different air pollution
control processes. Journal of the Air & Waste Management Association, 71(5),
553-563.
Evers, D. C., DiGangi, J., Petrlík, J., Buck, D. G., Šamánek, J., Beeler, B., & Regan, K.
(2014). Global mercury hotspots: new evidence reveals mercury contamination
regularly exceeds health advisory levels in humans and fish worldwide. BRI-IPEN
Science Communications Series, 34, 2014.
Finkelman, R. B. (1993). Trace and minor elements in coal. Inorganic geochemistry
(pp. 593-607). Springer, Boston, MA.
Gmelin, L. (1846). Hand Book of Chemistry Vol-6. Cavendish Society; London.
Grandjean, P., Satoh, H., Murata, K., & Eto, K. (2010). Adverse effects of
methylmercury: environmental health research implications. Environmental
Health Perspectives, 118(8), 1137-1145.
Greenwood, N. N., & Earnshaw, A. (2012). Chemistry of the Elements. Elsevier.
Hrdlicka, J.A., Seames, W.S., Mann, M.D., Muggli, D.S., & Horabik, C.A. (2008).
Mercury oxidation in flue gas using gold and palladium catalysts on fabric filters.
Environmental Science & Technology, 42 (17), 6677–6682.
Hsu, C. J., Chen, Y. H., & Hsi, H. C. (2020). Adsorption of aqueous Hg2+ and inhibition
of Hg0 re-emission from actual seawater flue gas desulfurization wastewater by
using sulfurized activated carbon and NaClO. Science of The Total Environment,
711, 135172.
Huang, W. J., Xu, H. M., Qu, Z., Zhao, S. J., Chen, W. M., & Yan, N. Q. (2016).
Significance of Fe2O3 modified SCR catalyst for gas-phase elemental mercury
oxidation in coal-fired flue gas. Fuel Processing Technology, 149, 23-28.
Karagas, M. R., Choi, A. L., Oken, E., Horvat, M., Schoeny, R., Kamai, E., & Korrick,
S. (2012). Evidence on the human health effects of low-level methylmercury
exposure. Environmental Health Perspectives, 120(6), 799-806.
Kaupp, M., & von Schnering, H. G. (1993). Gaseous mercury (IV) fluoride, HgF4: an
ab initio study. Angewandte Chemie International Edition in English, 32(6), 861-
863.
Li, C., Duan, Y., Tang, H., Zhu, C., Li, Y., Zheng, Y. & Liu, M. (2018) Study on the Hg
emission and migration characteristics in coal-fired power plant of China with an
ammonia desulfurization process. Fuel, 211, 621-628.
Li, X., Li, Z., Fu, C., Tang, L., Chen, J., Wu, T., Lin, C., Feng, X. & Fu, X. (2019b)
Fate of mercury in two CFB utility boilers with different fueled coals and air
pollution control devices. Fuel, 251, 651-659.
Li, X., Li, Z., Wu, T., Chen, J., Fu, C., Zhang, L., & Wang, Z. (2019a). Atmospheric
mercury emissions from two pre-calciner cement plants in Southwest China.
Atmospheric Environment, 199, 177-188.
Li, Z., Chen, X., Liu, W., Li, T., Chen, J., Lin, C., Sun, G. & Feng, X. (2019c) Evolution
of four-decade atmospheric mercury release from a coal-fired power plant in
North China. Atmospheric Environment, 213, 526-533.
Lide, D. R. (Ed.). (2004). CRC handbook of chemistry and physics (Vol. 85). Chemical
Rubber Company press.
Mlakar, T. L., Horvat, M., Vuk, T., Stergaršek, A., Kotnik, J., Tratnik, J., & Fajon, V.
(2010). Mercury species, mass flows and processes in a cement plant. Fuel, 89(8),
1936-1945.
Riedel, S., & Kaupp, M. (2009). The highest oxidation states of the transition metal
elements. Coordination Chemistry Reviews, 253(5-6), 606-624.
Riedel, S., Kaupp, M., & Pyykkö, P. (2008). Quantum chemical study of trivalent group
12 fluorides. Inorganic Chemistry, 47(8), 3379-3383.
Rizeq, R. G., Hansell, D. W., & Seeker, W. R. (1994). Predictions of metals emissions
and partitioning in coal-fired combustion systems. Fuel Processing Technology,
39(1-3), 219-236.
Sandheinrich, M. B., Bhavsar, S. P., Bodaly, R. A., Drevnick, P. E., & Paul, E. A. (2011).
Ecological risk of methylmercury to piscivorous fish of the Great Lakes region.
Ecotoxicology, 20(7), 1577-1587.
Srivastava, R. K., Hutson, N., Martin, B., Princiotta, F., & Staudt, J. (2006). Control of
mercury emissions from coal-fired electric utility boilers. Environmental Science
& Technology, 40(5), 1385-1393.
Su, S., Liu, L., Wang, L., Syed-Hassan, S. S. A., Kong, F., Hu, S., Wang, Y., Jiang, L.,
Xu, K., Zhang, A. & Xiang, J. (2017) Mass flow analysis of mercury
transformation and effect of seawater flue gas desulfurization on mercury removal
in a full-scale coal-fired power plant. Energy & Fuels, 31 (10), 11109-11116.
Suarez Negreira, A., & Wilcox, J. (2015). Uncertainty analysis of the mercury oxidation
over a standard SCR catalyst through a lab-scale kinetic study. Energy & Fuels,
29(1), 369-376.
Tang, N. & Pan, S. (2013) Study on mercury emission and migration from large scale
pulverized coal fired boilers. Journal of Fuel Chemistry and Technology, 41 (4),
484-490.
Tang, S., Wang, L., Feng, X., Feng, Z., Li, R., Fan, H. & Li, K. (2016) Actual mercury
speciation and mercury discharges from coal-fired power plants in Inner Mongolia,
Northern China. Fuel, 180, 194-204.
Tao, S., Li, C., Fan, X., Zeng, G., Lu, P., Zhang, X., & Fan, C. (2012). Activated coke
impregnated with cerium chloride used for elemental mercury removal from
simulated flue gas. Chemical Engineering Journal, 210, 547-556.
Uaciquete, D. L., Sakusabe, K., Kato, T., Okawa, H., Sugawara, K., & Nonaka, R.
(2021). Influence of unburned carbon on mercury chemical forms in fly ash
produced from a coal-fired power plant. Fuel, 300, 120802.
UNEP, (2019) "Global Mercury Assessment 2018. "
US EPA, (2012) "National emission standards for hazardous air pollutants from coal-
and oil-fired electric utility steam generating units and standards of performance
for dossil-fuel-fired electric utility, industrial-commercial institutional, and small
industrial-commercial-institutional steam generating units; Final Rule. "
US EPA, (2013) " National emission standards for hazardous air pollutants from coal-
and oil-fired electric utility steam generating units and standards of performance
for fossil-fuel-fired electric utility, industrial-commercial institutional, and small
industrial-commercial-institutional steam generating units; Rules and
Regulations. "
US EPA, (2017) " Method 30B-Determination of total vapor phase mercury emissions
from coal-fired combustion sources using carbon sorbent traps. "
Wang, F., Wang, S., Zhang, L., Yang, H., Wu, Q., & Hao, J. (2014). Mercury enrichment
and its effects on atmospheric emissions in cement plants of China. Atmospheric
environment, 92, 421-428.
Wang, F., Wang, S., Zhang, L., Yang, H., Wu, Q., & Hao, J. (2016). Characteristics of
mercury cycling in the cement production process. Journal of Hazardous
Materials, 302, 27-35.
Wang, S., Zhang, L., Li, G., Wu, Y., Hao, J., Pirrone, N., Sprovieri, F. & Ancora, M.
(2010) Mercury emission and speciation of coal-fired power plants in China.
Atmospheric Chemistry and Physics, 10 (3), 1183-1192.
Wilcox, J., Rupp, E., Ying, S. C., Lim, D. H., Negreira, A. S., Kirchofer, A., & Lee, K.
(2012). Mercury adsorption and oxidation in coal combustion and gasification
processes. International Journal of Coal Geology, 90, 4-20.
Won, J. H., & Lee, T. G. (2012). Estimation of total annual mercury emissions from
cement manufacturing facilities in Korea. Atmospheric Environment, 62, 265-271.
Yang, A. Y., Yan, Z. C., Hui, R. T., Shen, Z. Y., & Zhuang, K. (2015). The abundance,
distribution, and modes of occurrence of Hg in Chinese coals. Science Technology
and Engineering, 15(32), 1671-815.
Yorifuji, T., Tsuda, T., & Harada, M. (2013). Minamata disease: a challenge for
democracy and justice. Late Lessons from Early Warnings: Science, Precaution,
Innovation. Copenhagen, Denmark: European Environment Agency.
Yudovich, Y. E., & Ketris, M. P. (2005). Mercury in coal: A review: Part 1.
Geochemistry. International Journal of Coal Geology, 62(3), 107-134.
Zhang, C., Zhang, Y. H., Wang, Y. M., Wang, D. Y., Luo, C. Z., Xu, F., & He, X. Q.
(2017). Characteristics of mercury emissions from modern dry processing
cement plants in chongqing. Huanjing Kexue, 38(6), 2287-2293.
Zhang, L. (2007). Research on mercury emission measurement and estimate from
combustion resources. Zhejiang University, China (in Chinese).
Zhao, B., Li, Z., Zhou, W., (2019a). Research progress of catalysts for synergistic
denitrification and mercury removal. Zhejiang Xinan Chemical Industrial Group
Cooperation Limited company, 50 (2), 38–41.
Zhao, S., Pudasainee, D., Duan, Y., Gupta, R., Liu, M., & Lu, J. (2019b). A review on
mercury in coal combustion process: Content and occurrence forms in coal,
transformation, sampling methods, emission and control technologies. Progress
in Energy and Combustion Science, 73, 26-64.
Zhou, Q., Duan, Y., Zhu, C., Zhang, J., She, M., Wei, H., & Hong, Y. (2015). Adsorption
equilibrium, kinetics and mechanism studies of mercury on coal-fired fly ash.
Korean Journal of Chemical Engineering, 32(7), 1405-1413.
Zhou, W., Yu, L., Li, D., & Shiau, Y. C. (2016). Thermodynamic effects of alkaline
earth metals on homogenous mercury oxidation during calcium carbonate (CaCO3)
and coal combustion. Toxicological & Environmental Chemistry, 98(3-4), 303-
312.
Zhou, Z. J., Liu, X. W., Zhao, B., Chen, Z. G., Shao, H. Z., Wang, L. L., & Xu, M. H.
(2015). Effects of existing energy saving and air pollution control devices on
mercury removal in coal-fired power plants. Fuel Processing Technology, 131,
99-108.
行政院環保署空氣品質保護處,固定污染源汞排放管制與空品監測成果,2020。
行政院環保署環境檢驗所,水中汞檢測方法-氧化/吹氣捕捉/冷蒸氣原子螢光光
譜法(NIEA W331.50B)。
行政院環境保護署環境檢驗所,排放管道中重金屬檢測方法 (NIEA A302.73C),
2010。
行政院環境保護署環境檢驗所,硫、氯元素含量檢測方法-燃燒管法 (NIEA
M402.01C)。
行政院環境保護署環境檢驗所,碳、氫、硫、氧、氮元素含量檢測方法-元素分
析儀法 (NIEA M403.02B)。 |