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Molten Salt Electrolysis for Sustainable Metals Extraction and Materials Processing 41 [3] Fray, D.J. (1988). Potential for fused salt electrolysis for metal winning and refining, Metallurgical Processes for the Year 2000 and Beyond, Sohn, H.Y., Geskin, E.S., ed., TMS, Warrendale, PA, pp. 493-516. [4] Inman, D. (1987). Electrodeposition from molten salts, Molten Salt Chem., Mamantov, G. and Marassi, R., ed., D. Reidel Publishing Company, Boston, MA., pp. 417-424. [5] Fray, D.J. (2000). Aspects of technology transfer, Metall. Mater. Trans. B, 31B, pp. 1153-1162. [6] Fray, D.J. (1978). Packed bed electrorefining and electrolysis, US Pat. No. 4,118,292, Oct. 3, 1978. [7] Fray, D.J. (1986). Electrode for electrorefining, GB Pat. 8628137, Nov. 25, 1986. [8] Charles, J.A. and Fray, D.J. (1988). Metals separation process, WO 88/02793, April 21, 1988. [9] Fray, D.J. and Driscoll, K.J. (1992). Development of energy efficient fused salt electrorefining cells, Electrochem. Eng. Environment 92, Symposium Series No. 127, Inst. Chem. Eng., Warwickshire, pp. 1-9. [10] Cox, A. and Fray, D.J. (1996). Application of centrifugal fields in fused salt electrowinning with a view to reducing electrolytic energy consumption, Metall. Mater. Trans. B, 27B, pp. 889-894. [11] Castrillejo, Y., Martinez, A.M., Bermejo, M.R., Vega, M.S., Haarberg, G.M., and Picard, G.S. (1999). Possibilities of chemical treatment of raw materials and the subsequent electrowinning of metal in molten chlorides - Review of previous results, Advances in Molten Salts. From Structural Aspects to Waste Processing, Gaune-Escard, M., ed., Begell House, New York, pp. 78-92. [12] Choate, W.T. and Green, J.A.S. (2003). U.S. energy requirements for aluminum production: Historical perspective, theoretical limits and new opportunities, prepared under Contract to BCS, Incorporated, Columbia, MD., U.S. Dept. Energy, Energy Efficiency and Renewable Energy, Washington, D.C. [13] Winter, D.G. and Strachan, A.M. (1977). Advances in Extractive Metallurgy, Jones, M.J., ed., Inst. Min. Metall., London, pp. 177-184. [14] Tiwari, B.L. and Sharma, R.A. (1984). Electrolytic removal of magnesium from scrap aluminium, J. Metals, July, pp. 41-43. [15] Syivestre, V. (1986). Cell for electrolytic purification of aluminum, US Pat. No. 4,601,804, Jul. 22, 1986. [16] Sharma, I.G. and Mukherjee, T.K. (1986). A study on purification of metallurgical grade silicon by molten salt electrorefining, Metall. Trans. B, 17B, pp. 395-397. [17] Slatin, H.L. (1959). Electrolytic production of aluminum, US Pat. No. 2,919,234, Dec. 29, 1959. [18] Jarrett, N., Frank, W.B., and Keller, R. (1981). Advances in the smelting of aluminum, Metall. Treatises, Tien, J.K. and Elliott, J.F., ed., AIME, Warrendale, PA, pp. 137-157. [19] Grjotheim, K., Kvande, H., and Qin, Z.X. (1995). Key improvements to Hall-Heroult since the end of world war II, JOM, Nov., pp. 32-35. [20] Sadoway, D.R. (1998). Advances and innovations in the extraction of aluminium and magnesium, Molten Salt Forum, 5-6, pp. 43-48. [21] Edwards, L. and Kvande, H. (2001). Inert anodes and other technology changes in the aluminum industry – The benefits, challenges, and Impact on present technology, JOM, May, p. 28.PDF Image | MOLTEN SALT ELECTROLYSIS
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