Spectroscopic determination of the solubility of several substances in liquefied gases according to electronic absorption bands

1. M. O. Bulanin, “Infrared spectroscopy in liquefied gases,” J. Mol. Struct.,19a, No.1, 59–79 (1973).

   Google Scholar 

2. E. Szczepaniec-Cieciak, B. Dabrowska, and M. Lagan, “The solubility of solidified hydrocarbons in liquid N₂,” Cryogenics,17, No. 11, 621–627 (1977).

   Google Scholar 

3. R. G. Amamchyan, V. V. Bertsev, and M. O. Bulanin, “Analysis of cryogenic solutions according to IR absorption spectra,” Zavod. Lab.,39, No. 4, 432–434 (1973).

   Google Scholar 

4. V. V. Bertsev, M. O. Bulanin, L. A. Zhigula, et al., “Infrared spectra of solutions in liquefied gases,“ in: Molecular Spectroscopy [in Russian], No. 2, LGU, Leningrad (1973), pp. 81–93.

   Google Scholar 

5. R. G. Amamchyan, V. V. Bertsev, and M. O. Bulanin, “Investigation of phase equilibria at low temperatures by IR spectroscopy,” Zh. Fiz. Khim.,47, No. 10, 2665–2666 (1973).

   Google Scholar 

6. V. V. Bertsev, “Investigation of solutions in liquefied gases according to IR absorption spectra,“ Author's Abstract of Candidate's Dissertation, Leningrad (1973).

7. V. V. Bertsev, M. O. Bulanin, and G. Ya. Zelikina, “Analysis of cryogenic solutions on the basis of electronic absorption spectra,” Zavod. Lab.,41, No. 8, 960–962 (1975).

   Google Scholar 

8. G. Ya. Zelikina, T. G. Meister, and V. V. Bertsev, “Determination of the solubility of several substances in liquefied gases from absorption spectra,” Zh. Fiz. Khim.,52, No.10, 2709 (1978).

   Google Scholar 

9. G. Ya. Zelikina, V. V. Bertsev, and T. G. Meister, “Electronic absorption spectra of several cryosystems,“ in: Molecular Spectroscopy [in Russian], No. 4, LGU, Leningrad (1977), p. 41–56.

   Google Scholar 

10. M. P. Malkov, I. B. Danilov, A. G. Zel'dovich, et al., Reference Book on the Physicotechnical Principles of Cryogenics [in Russian], Energiya, Moscow (1973).

    Google Scholar 

11. A. Sinnock and B. Smith, “Refractive indices of the condensed inert gases,” Phys. Rev.,181. No. 3, 1297–1307 (1969).

    Google Scholar 

12. B. Sowers, M. Williams, E. Arakawa, et al., “Optical properties of liquid n-hexane and cyclohexane in the VUV,” J. Chem. Phys.,57, No. 1, 167–170 (1972).

    Google Scholar 

13. V. V. Bertsev, G. Ya. Zelikina, and T. G. Meister, “Absolute intensity of the¹A_1g →\({}^{\text{1}}{\text{E}}_{{\text{1}}_{\text{u}} } \) of benzene dissolved in argon,” Opt. Spektrosk.,39, No. 1, 192–193 (1975).

    Google Scholar 

14. J. Platt and H. Klevens, “Absolute absorption intensities of alkylbenzenes in the 2250– 1700 Å region,” Chem. Rev.,41, No. 2, 301–303 (1947).

    Google Scholar 

15. J. Rabalais, J. McDonald, S. McGlynn, et al., “Electronic spectroscopy of isoelectronic molecules. II.,” Chem. Rev.,71, No. 1, 73–108 (1971).

    Google Scholar 

16. L. M. Sverdlov, M. A. Kovner, and E. P. Krainov, Vibrational Spectra of Polyatomic Molecules [in Russian], Fizmatgiz, Moscow (1970).

    Google Scholar 

17. J. Lake and A. Harrison, “Absorption of acyclic oxygen compounds in the VUV. III.,” J. Chem. Phys.,30, No. 2, 361–364 (1959).

    Google Scholar 

18. W. Harschbarger, A. Skerbele, and E. Lassettre, “Generalized oscillator strength of the A-X transition of ammonia,” J. Chem. Phys.,54, No. 9, 3784–3789 (1971).

    Google Scholar 

19. K. Innes, J. Byrne, and I. Ross, “Electronic states of azabenzenes: a critical review,“ J. Mol. Spectrosc.,22, No. 2, 125–147 (1967).

    Google Scholar 

20. G. Preston and J. Prausnitz, “Thermodynamics of solid solubility in cryogenic solvents,” Ind. Eng. Chem. Process Des. Develop.,9, No. 2, 264–271 (1970).

    Google Scholar 

21. J. Hildebrand and R. Scott, Regular Solutions, Prentice-Hall (1962).

Download references