REFERENCES
- R. W. BENEDICT and H. F. McFARLANE, “EBR-II Spent Fuel Treatment Demonstration Project Status,” Radwaste Magazine, 5, 4, 23 (1998).
- J. J. LAIDLER et al., “Development of Pyroprocessing Technology,” Prog. Nucl. Energy, 31, 131 (1997).
- S. VAVILOV, T. KOBAYASHI, and M. MYOCHIN, “ Principle and Test Experience of the RIAR’s Oxide Pyro-Process,” J. Nucl. Sci. Technol., 41, 1018 (2004).
- Y. J. SHIN et al., “Development of Advanced Spent Fuel Management Process,” KAERI/RR-2128/2000, Korea Atomic Energy Research Institute (2000).
- T. INOUE and T. YOKOO, “Advanced Fuel Cycle with Electrochemical Reduction,” Proc. Global 2003, New Orleans, Louisiana, November 16–20, 2003, American Nuclear Society (2003).
- J. SERP, M. ALLIBERT, A. LE TERRIER, R. MALMBECK, M. OUGIER, J. REBIZANT, and J.-P. GLATZ, “Electroseparation of Actinides from Lanthanides on Solid Aluminum Electrode in LiCl-KCl Eutectic Melts,” J. Electrochem. Soc., 152, C167 (2005).
- T. USAMI, M. KURATA, T. INOUE, and J. JENKINS, “Behavior of Actinide Elements in the Lithium Reduction Process(I) —Feasibility of the Li Reduction Process to UO2 and PuO2,” Komae Research Laboratory report T-99089, Central Research Institute of Electric Power Industry (2000).
- G. K. JOHNSON, R. D. PIERCE, D. S. POA, and C. C. McPHEETERS, “Pyrochemical Recovery of Actinide Elements from Spent Light Water Reactor Fuel,” ANL/CMT/CP-80020, Argonne National Laboratory (1994).
- E. J. KARELL, R. D. PIERCE, and T. P. MULCAHEY, “Treatment of Oxide Spent Nuclear Fuel Using the Lithium Reduction Process,” ANL/CMT/CP-89562, Argonne National Laboratory (1996).
- E. J. KARELL, K. V. GOURISHANKAR, J. L. SMITH, L. S. CHOW, and L. REDEY, “Separation of Actinides from LWR Spent Fuel Using Molten-Salt-Based Electrochemical Processes,” Nucl. Technol., 136, 342 (2001).
- T. KATO, T. USAMI, R. YUDA, M. KURATA, and H. MORIYAMA, “Development of Reduction Technology for Oxide Fuel-Behavior of Rare-Earths in Li Reduction Process,” Komae Research Laboratory report T99009, Central Research Institute of Electric Power Industry (2000).
- H. HAYASHI, and K. MINATO, “Stability of Lanthanide Oxides in LiCl-KCl Eutectic Melt,” J. Phys. Chem. Solids, 66, 422 (2005).
- G. Z. CHEN, D. J. FRAY, and T. W. FARTHING, “Direct Electrochemical Reduction of Titanium Dioxide to Titanium in Molten Calcium Chloride,” Nature, 407, 361 (2000).
- S. D. HERRMANN, S. X. LI, and M. F. SIMPSON, “Electrolytic Reduction of Spent Light Water Reactor Fuel: Bench-Scale Experiment Results,” J. Nucl. Sci. Technol., 44, 3, 361 (2005).
- R. K. AHLUWALIA and H. K. GEYER, “The GC Computer Code for Flow Sheet Simulation of Pyrochemical Processing of Spent Nuclear Fuels,” Nucl. Technol., 116, 180 (1996).
- T. FUJII, T. NAGAI, N. SATO, O. SHIRAI, and H. YAMANA, “Electronic Absorption Spectra of Lanthanides in a Molten Chloride II. Absorption Characteristics of Neodymium(III) in Various Molten Chlorides,” J. Alloys Compounds 393, L1 (2005).
- K.-K. PARK et al., “Development of Chemical Technology in Nuclear Fuel Cycle,” KAERI/RR-2423, pp. 202–207, Korea Atomic Energy Research Institute (2003).