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Molten Salt Electrolysis for Sustainable Metals Extraction and Materials Processing 47 [109] Whites, J.C., Laughlim, J., and Loutfy, R.O. (2007). The production of titanium from a composite anode, Innovations in Titanium Technology, Gungor, M.N., Imam, M.A., and Froes, F.H.S. ed., TMS, Warrendale, Pa., pp. 117-125. [110]Maity, S.K., Shekhar, M.C., and Ananth, V. (2009). An exploratory study of electrodeposition of titanium using titanium dioxide carbon composite anode and molten aluminium cathode, Trans. IMM C, 118 (1), pp. 10-17. [111] Jiao, S.Q. and Zhu, H.M. (2006). Novel metallurgical process for titanium production, J. Mater. Res., 21 (9), pp. 2172-2175. [112] Jiao, S.Q. and Zhu, H.M. (2007). Electrolysis of Ti2CO solid solution prepared by TiC and TiO2, J. Alloys Compd., 438, pp. 243-246. [113] Yan, X.Y. and Fray, D.J. (2005). Morphology and formation mechanism of niobium-based superconductors synthesized by electro-deoxidation of oxide precursors in molten chlorides, 7th International Symposium on Molten Salts Chemistry & Technology, Toulouse, France, September, pp. 123-127. [114] Rosenkilde, C. (2007). Method for production of carbon materials, WO 2007/046713 A1, April 26, 2007. [115] Fray, D.J., Schwandt, C., and Dimitrov, A. (2006). Electrochemical method, apparatus and carbon product, WO 2006/037955 A1, April 13, 2006. [116]Macklin, W.J. and Fray, D.J. (2001). Rechargeable lithium cell having an anode comprised of carbon nanotubes, WO 01/15251, March 1, 2001. [117] Cleland, J.H. and Fray, D.J. (1979). Packed-bed electro-refining of aluminium, bismuth and zinc alloys, Trans. IMM C, 88, pp. C191-C196. [118] Yan, X.Y. (2008). Chemical and electrochemical processing of aluminum dross using molten salts, Metall. Mater. Trans. B, 39B, pp. 348-363. [119] Pierce, R.D., Johnson, T.R., McPheeters, C.C., and Laidler, J.J. (1993). Progress in the pyrochemical processing of spent nuclear fuels, JOM, February, pp. 40-44. [120] Karell, E.J., Pierce, R.D., and Mulcahey, T.P. (1996). Treatment of oxide spent fuel using the lithium reduction process, Proceedings of the embedded topical meeting on DOE spent nuclear fuel and fissile material management, Reno, Nevada, June 16-20, 1996, pp. 352-358. [121]Gourishankar, K.V. and Karell, E. (1999). Application of lithium in molten-salt reduction processes, Light Metals 1999, Eckert, C.E., ed., TMS, Warrendale, PA, pp. 1123-1128. [122] Li, S.X., Herrmann, S.D., Simpson, M.F., and Wahlquist, D.R. (2003). Electrochemical reduction of uranium oxide fuel in a molten LiCl/Li2O system, Electrochemistry in Mineral and Metal Processing VI Proceedings of the International Symposium, 2003- 18, Doyle, F.M., Kelsall, G.H., and Woods, R., ed., The Electrochem. Soc., Inc., Pennington, New Jersey, pp. 401-409. [123] Bychkov, A.V., Vavilov, S.K., Porodnov, P.T., Skiba, O.V., Popkov, G.P., and Pravdin, A.K. (1998). Pyrochemical reprocessing of iiadiated mixed oxide fuel in molten salts, Molten Salt Forum, 5-6, pp. 525-528. [124]Shin, Y.J., Kim, I.S., Ro, S.G., and Park, H.S. (1998). Application of molten salt technology to PWR spent fuel storage, Molten Salt Forum, 5-6, pp. 529-532. [125] Anderson, R.N. and Parlee, N.A.D. (1974). Reducing metal oxides – by carbothermic method and recovering metal in pure form from resulting reaction mixture, US Pat. 3,794,482 A, Feb. 26, 1974.PDF Image | Molten salt electrolysis for sustainable metals extraction
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