REFERENCES
- I.P. HERMAN and J.B. MARLING, “IR Photolysis of CDF3: A Study in Kinetics of Multiple-Photon nissociation with Applications in Deuterium Separation,” Chem. Phys. Lett., 64, 75 (1979).
- S.A. TUCCIO and A. HARTFORD Jr., “Deuterium Enrichment via Selective Dissociation of Fluoroform-d with a Pulsed CO2 Laser,” Chem. Phys. Lett., 65, 234 (1979).
- J.B. MARLIMG, I.P. HERMAN AND S.J. THOMAS, “Deuterium Separation at High Pressure by Nanosecond CO2 Laser Multiphoton Dissociation,” J. Chem. Phys., 72, 5603 (1980).
- D.K. EVANS, R.D. McALPINE and H.M. ADAMS, “The Multiphoton Absorption and Decomposition of Fluoroform: Laser Isotope Separation of Deuterium,” J. Chem. Phys., 77, 3551 (1982).
- J.A. O’NEILL and J.R. ROBINS, “The Effects of Wavelength, Temperature and Trifluoromethane-H Buffer Gas Pressure on the Infrared Multiphoton Decomposition of Trifluoromethane-D,” J. Chem. Phys., 81, 1825 (1984).
- (a) E.A. SYMONS, M.J. CLERMONT, AND L.A. CODERRE, Hydrogen Isotope Exchange between Fluoroform (CF3H) and Water. 2. Catalysis by Hydroxide Ion in the Presence of Added Dimethyl Sulfoxide,” J. Am. Chem. Soc., 103, 3131 (1981). (b) E.A. SYMONS, J. DOUGLAS BONNETT, and M. de LURDES MARTINS, “Hydrogen Isotope Exchange between Fluoroform (CF3H) and Water. 4. Catalysis by NaOH and Anionic Resin above 100°C as an Alternative to DMSO Addition to Rate Enhancement,” Can. J. Chem., 61, 2627 (1983).
- M. HANOI and J.R. ROBINS, “Demonstration of a Deuterium Recovery System for a Laser Heavy Water Process Based on Trifluoromethane (CF3D) Dissociation,” Ontario Hydro Research Division Report, E82-24-K (1982).
- K.B. WOODALL, “A Multi photon Laser Heavy Water Process Based On Freon 23 (CF3H),” Ontario Hydro Research Division Report, 80-206-K (1980).
- I.P. HERMAN and J.B. MARLING, “Infrared Spectrum of CTF3 and Implications toward Tritium Isotope Separation by Infrared Laser Multiple-Photon Dissociation of Halogenated Methanes,” J. Phys. Chem., 85, 493 (1981).
- Y. ISHIKAWA, S. ARAI and R. NAKANE, “Calculation of Fundamental Vibration Frequencies of Tritium-Substituted Halomethanes for Tritium Separation by Infrared Lasers,” J. Nucl. Sci. Tech., 17, 275 (1980).
- K. TAKEUCHI, S. SATOOKA, O. KIJRIHARA, I. INOUE and Y. MAKIDE, “Laser Tritium Isotope Separation Using Trifluoromethane,” 1983 Progress Report, Japanese Institute of Physical and Chemical Researcn.
- K.B. WOODALL, L. MANNIK, J.A. O’NEILL, D.L. MADER, S.B. NICKERSON, J.R. ROBINS, AND F.E. BARTOSZEK, “Laser Isotope Separation - A Mew Class of Chemical Process,” Proceedings of the 33rd Chemical Engineering Conference of the Canadian Society of Chemical Engineering, p334
- J.C. VANDERLEEOEN, “Depletion Optimization and Photon Efficiency in Laser Isotope Separation of Deuterium,” APPL.OPT., 17, 785 (1978). O. 838 (1972).
- R.L. ABRAMS, “Coupling Losses in Hollow Waveguide Laser Resonators,” IEEE J. Q. EL., QE-8, 838 (1972).
- E.A.J. MARCATILI and R.A. SCHMELTZER, “Hollow Metallic and Dielectric Waveguides for Long Distance Optical Transmission and Lasers,” Bell Syst. Tech. J., 43, 1783 (1964).
- R.E. TREYBOL, “Mass-Transfer Operations”, 3rd Edition, McGraw-Hill Book Company, Toronto (1980).