would probably be most easily adapted into a lunar processing plant if it were compatible with the general chemical system that is chosen for beneficiation and metals separation. Acknowledgment — A part of this work was supported by the U.S. Department of Energy under Contract No. ANL-31-109-39-4212 for a Survey of Metalwinning Processes, administered by Argonne National Laboratories. REFERENCES 1. R.D. Waldron, T.E. Erstfeld, and D.R. Criswell, The Role of Chemical Engineering in Space Manufacturing, Chemical Engineering 86, 80, 1979. 2. Battelle’s Columbus Laboratories, A Survey of Electrochemical Metal Winning Processes, Report No. ANL/OEPM-79-3 to Argonne National Laboratories, 1979. 3. Battelle’s Columbus Laboratories, Energy Use Patterns in Metallurgical and Nonmetallic Mineral Processing, Phase 4 — Energy Data and Flowsheets, High Priority Commodities (Report PB245 759/AS); Phase 5 — Energy Data and Flowsheets, Intermediate-Priority Commodities (Report PB 246 357/AS); Phase 9 — Areas Where Alternative Technologies Should be Developed to Lower-Energy Use in Production to Intermediate-Priority Commodities (Report PB 261 153/AS) to the Bureau of Mines, 1975. 4. M. Paul Lugagne, The Magnetherm Process for the Production of Magnesium, Erzmetall 31, 310, 1978. 5. R.D. Halliday and P. McIntosh, Laboratory Cell and Hydrodynamic Model Studies of Magnesium Chloride Reductions in Low-Density Electrolytes, J. Electrochem. Soc. 120, 858, 1973. 6. Kh. L. Strelets, Electrolytic Production of Magnesium, Israel Program for Scientific Translations, Keter, Jerusalem, 1977. 7. C.L. Mantell, Industrial Electrochemistry, McGraw-Hill, New York, 1950. 8. M.L. Kronenberg, Gas Depolarized Graphite Anodes for Aluminum Electrowinning, J. Electrochem. Soc. 116, 1160, 1969. 9. J. Wurm, Electrolytische Beschichtungen aus der Salzschmelze, Galvanotechnik 70, 420, 1979. 10. A.E. Austin, Silicon Electrodeposition, U.S. Patent No. 3,990,953, November 9, 1976.
RkJQdWJsaXNoZXIy MTU5NjU0Mg==