Publications -S-
  • Sabnis, S.T. and L.A. Wenzel, Joule-Thomson effects for mixtures of helium-nitrogen-methane and hydrogen-nitrogen-methane. AIChE J., 1971. 17(6): p. 1372-80.
  • Sagara, H., Y. Arai, and S. Saito, Application of the BWR equation to predict the vapor-liquid equilibria of hydrogen-hydrocarbon systems. J. Chem. Eng. Jpn., 1972. 5(4): p. 418-22.
  • Sagara, H., Y. Arai, and S. Saito, Vapor-liquid equilibria of binary and ternary systems containing hydrogen and light hydrocarbons. J. Chem. Eng. Jpn., 1972. 5(4): p. 339-48.
  • Sagara, H., et al., Vapor-liquid equilibria and Henry's constants for ternary systems containing hydrogen and light hydrocarbons. J. Chem. Eng. Jpn., 1975. 8(2): p. 98-104.
  • Sagara, H., Y. Arai, and S. Saito, Enthalpies of the hydrogen-light hydrocarbon binary mixtures at elevated pressures and low temperatures. J. Chem. Eng. Jpn., 1977. 10(2): p. 95-100.
  • Sage, B.H., R.H. Olds, and W.N. Lacey, Two gaseous mixtures containing hydrogen and nitrogen, thermodynamic properties. Ind. Eng. Chem., 1948. 40(8): p. 1453-1459.
  • Saika, A., J.I. Musher, and N. Miyabe, Use of the nonsymmetrical wavefunction. III. Magnetic susceptibility of molecular hydrogen. J. Chem. Phys., 1972. 56(7): p. 3312-4.
  • Sakai, K., A. Koide, and T. Kihara, Intermolecular forces for hydrogen, nitrogen and acetylene. Chem. Phys. Lett., 1977. 47(3): p. 416-20.
  • Salceanu, C. and S. Bojin, On the thermal conductivity of gases and vapors (in French). C. R. Hebd. Seances Acad. Sci., 1956. 243(3): p. 237-9.
  • Sancier, K.M. and H. Wise, Diffusion coefficient measurements for gas mixture of atomic and molecular hydrogen. 1969: Stanford Res. Inst., Tech. Rep. SRI-27-PU, 25 pp.
  • Sancier, K.M. and H. Wise, Diffusion and heterogeneous reaction. XI. Diffusion coefficient measurements for gas mixture of atomic and molecular hydrogen. J. Chem. Phys., 1969. 51(4): p. 1434-8.
  • Sandor, E. and S.O. Ogunade, Structure and phase transition in solid hydrogen and deuterium sulphides. Nature, 1969. 224(5222): p. 905-7.
  • Sasai, M., Instabilities of hydrogen bond network in liquid water. J. Chem. Phys., 1990. 93(10): p. 7329-41.
  • Sawford, B.L., T.H. Spurling, and D.S. Thurley, The diffusion thermoeffect (Dufour effect) in gaseous mixtures of hydrogen and carbon dioxide. Aust. J. Chem., 1970. 23(7): p. 1311-20.
  • Saxena, S.C. and P.A. Pardeshi, Various approximations for the isotopic thermal diffusion factor. II. Application to hydrogen isotopes. Indian J. Phys., 1962. 36: p. 13-24.
  • Saxena, A.C. and D.B. Robinson, Phase behavior of the methane-carbon dioxide-n-butane and methane-hydrogen sulphide-n-butane systems. Can. J. Chem. Eng., 1969. 47(1): p. 69-75.
  • Saxena, S.C. and V.K. Saxena, Thermal conductivity data for hydrogen and deuterium in the range 100-1100 degrees C. J. Phys. A, 1970. 3: p. 309-20.
  • Sceats, M.G. and S.A. Rice, The water-water pair potential near the hydrogen bonded equilibrium configuration. J. Chem. Phys., 1980. 72(5): p. 3236-47.
  • Schaefer, K., The second virial coefficient of the different modifications of light and heavy hydrogens. I. Experimental determination (in German). Z. Phys. Chem., 1937. 36B(2): p. 85-104.
  • Schaefer, K., The second virial coefficients of the various modifications of the light and heavy hydrogens. II. Theoretical calculation (in German). Z. Phys. Chem., 1937. 38B(2/3): p. 187-208.
  • Schaefer, K., On the vapor pressure difference and the molecular heats of ortho- and para-hydrogen (in German). Z. Phys. Chem., 1939. 42B(5): p. 380-94.
  • Schaefer, C.A. and G. Thodos, Reduced thermal conductivity correlation. Gaseous and liquid hydrogen. Ind. Eng. Chem., 1958. 50(10): p. 1585-8.
  • Schaefer, C.A. and G. Thodos, Reduced density correlation for hydrogen: liquid and gaseous states. AIChE J., 1959. 5(2): p. 155-8.
  • Schafer, K., The Second Virial Coefficient of Several Modified Light and Heavy Hydrogens. 1. Experimental Determination. Z. Phys. Chem., 1937. 36(2): p. 85-104.
  • Schaffer, S.K. and J.M. Prausnitz, Correlation of hydrogen solubilities in nonpolar solvents based on scaled-particle theory. AIChE J., 1981. 27(5): p. 844-8.
  • Schalkwijk, J.C., Precise isothermals. V. The isothermal of hydrogen at 20 degrees C. up to 60 atmospheres. Commun. Phys. Lab. Univ. Leiden, 1901(70): p. 3-21.
  • Schames, L., General improvement of the equation of state; special equation of state for hydrogen. 1963: Redstone Sci. Inform. Center, Transl. RSIC-73, 9 pp.
  • Schirdewahn, J., A. Klemm, and L. Waldmann, Thermal diffusion in D(2)-HT and other hydrogen mixtures (in German). Z. Naturforsch., 1961. 16A(2): p. 133-44.
  • Schlapbach, L. and A. Zuttel, Hydrogen-storage materials for mobile applications. Nature, 2001. 414: p. 353-358.
  • Schmauch, G.E. and A.H. Singleton, Technical aspects of ortho-parahydrogen conversion. 1964: Air Prod. Chem., Inc., Allentown, Pa., Pap., 40 pp.
  • Schmidt, F., Diffusion and ortho-para conversion in solid hydrogen. Phys. Rev. B, 1974. 10(10): p. 4480-4.
  • Schmidt, J.W., M. Nielsen, and W.B. Daniels, Coherent inelastic neutron scattering study of solid orthodeuterium at high pressure. Phys. Rev. B, 1984. 30(11): p. 6308-19.
  • Schneider, E., Correction to my work: "On the thermal conductivity of air and hydrogen" (in German). Ann. Phys. (Leipzig), 1926. 80(10): p. 215-6.
  • Schneider, E., On the thermal conductivity of air and hydrogen (in German). Ann. Phys. (Leipzig), 1926. 79(3): p. 177-203.
  • Schneider, T., Metallic hydrogen. Solid State Commun., 1969. 7(12): p. 875-6.
  • Schoen, W., R. Wiechers, and D. Woermann, Deuterium isotope effects in binary critical mixtures. J. Chem. Phys., 1986. 85(5): p. 2922-8.
  • Schott, W., H. Rietschel, and W. Glaeser, Para-ortho transitions in solid hydrogen. Phys. Lett. A, 1968. 27(8): p. 566-7.
  • Schott, W., Inelastic scattering of slow neutrons by solid and liquid hydrogen (in German). Z. Phys., 1970. 231(3): p. 243-65.
  • Schott, W., Molecular rotation in condensed hydrogen (in German). Z. Angew. Phys., 1970. 30(4): p. 293-5.
  • Schou, J. and H. Sorensen, The penetration depth of 0.5-3-keV electrons in solid hydrogen and deuterium. J. Appl. Phys., 1978. 49(2): p. 816-21.
  • Schouten, J.A., L.C. van den Bergh, and M.J. Trappeniers, Demixing in a molecular hydrogen-helium mixture up to 50 kbar. Chem. Phys. Lett., 1985. 114(4): p. 401-4.
  • Schramm, B., Elias, E., Pilger, R., Second interaction virial coefficients of argon-molecular hydrogen, Chem. Phys. Lett., 1982, 88: p. 459-61.
  • Schramm, B., Elias, E., Kern, L., Natour, G., Schmitt, A., Weber, C., Precise measurements of second virial coefficients of simple gases and gas mixtures in the temperature range below 300 K, Ber. Bunsen-Ges. Phys. Chem., 1991, 95: p. 615-21.
  • Schuch, A.F. and R.L. Mills, Crystal structure of deuterium at low temperatures. Phys. Rev. Lett., 1966. 16(14): p. 616-8.
  • Schuch, A.F., R.L. Mills, and D. Depatie, On the lambda-anomaly in hydrogen and deuterium. 1967: Los Alamos Sci. Lab., Rep. LA-DC-8458, 13 pp.
  • Schuch, A.F., R.L. Mills, and D.A. Depatie, Crystal-structure changes in hydrogen and deuterium. Phys. Rev., 1968. 165(3): p. 1032-40.
  • Schuette, R. and K. Koerting, The temperature dependence of the thermal diffusion factors of ortho- and para-deuterium in the region of 23 degrees K - 165 degrees K (in German). Z. Phys. Chem. (Wiesbaden), 1970. 71(4/6): p. 329-31.
  • Schwalbe, L.A. and E.R. Grilly, A review of deuterium triple-point temperatures. J. Phys. Chem. Ref. Data, 1984. 13(3): p. 687-93.
  • Schwalbe, L.A., Recent progress in deuterium triple-point measurements. J. Phys. Chem. Ref. Data, 1986. 15(4): p. 1351-6.
    Schweizer, K.S. and F.H. Stillinger, High pressure phase transitions and hydrogen-bond symmetry in ice polymorphs. J. Chem. Phys., 1984. 80(3): p. 1230-40.
  • Scopazzi, C. and D. White, Spin-lattice relaxation in the ordered state of paradeuterium. J. Chem. Phys., 1974. 60(1): p. 323-4.
  • Scott, G.A. The isotherms of hydrogen, carbon monoxide and their mixtures. in Proc. R. Soc. London, Ser. A. 1929.
  • Scott, R.B., et al., The vapor pressures and derived thermal properties of hydrogen and deuterium. J. Chem. Phys., 1934. 2: p. 454-64.
  • Scott, R.B. and F.G. Brickwedde, The vapor pressure of hydrogen deuteride. Bull. Am. Phys. Soc., 1935. 10(3): p. 9-10.
  • Scott, R.B. and F.G. Brickwedde, Molecular volumes and expansivities of liquid normal hydrogen and parahydrogen. J. Res. Natl. Bur. Stand., 1937. 19: p. 237-48.
  • Scuri, F., et al., Magnetic birefringence measurement in hydrogen and deuterium gases. J. Chem. Phys., 1986. 85(4): p. 1789-94.
  • Seagrave, J.D. Elastic scattering of fast neutrons by liquid hydrogen, deuterium, tritium and by He(3). in Proc. Symp. Few Body Probl., Light Nucl., Nucl. Interact. 1968.
  • Seagrave, J.D., et al., Elastic scattering and polarization of fast neutrons by liquid deuterium and tritium. Ann. Phys. (N. Y.), 1972. 74(1): p. 250-99.
  • Seal, P. and P.K. Bandyopadhyay, Contributions of non-spherical interactions to the second virial coefficient of ethane and hydrogen sulphide gases. Indian J. Phys., 1974. 48(8): p. 684-9.
  • Sears, V.F. and J. Van Kranendonk, Theory of the Q branch of the infrared spectrum of solid hydrogen. Can. J. Phys., 1964. 42(5): p. 980-1003.
  • Sebastian, H.M., et al., Gas-liquid equilibrium in mixtures of hydrogen and quinoline. J. Chem. Eng. Data, 1978. 23(4): p. 305-8.
  • Sebastian, H.M., et al., Gas-liquid equilibrium of the hydrogen/bicyclohexyl system at elevated temperatures and pressures. J. Chem. Eng. Data, 1978. 23(2): p. 167-70.
  • Sebastian, H.M., et al., Vapor-liquid equilibria in hydrogen + 9, 10-dihydrophenanthrene mixtures. J. Chem. Eng. Data, 1979. 24(4): p. 343-5.
  • Sebastian, H.M., H.M. Lin, and K.C. Chao, Gas-liquid equilibria in ternary mixtures of hydrogen + methane + 1-methylnaphthalene at elevated temperatures and pressures. Fluid Phase Equilib., 1980. 5(1/2): p. 89-95.
  • Sebastian, H.M., et al., Gas-liquid equilibrium in the hydrogen + n-decane system at elevated temperatures and pressures. J. Chem. Eng. Data, 1980. 25(1): p. 68-70.
  • Sebastian, H.M., et al., Gas-Liquid Equilibrium in the Hydrogen + n-Decane System at Elevated Temperatures and Pressures. J. Chem. Eng. Data, 1980. 25: p. 68-70.
  • Sebastian, H.M., H.-M. Lin, and K.-C. Chao, Vapor-liquid equilibrium in ternary mixtures of hydrogen + carbon dioxide + tetralin. J. Chem. Eng. Data, 1981. 26(3): p. 281-3.
  • Sebastian, H.M., H.-M. Lin, and K.-C. Chao, Vapor-liquid equilibrium of the hydrogen + carbon dioxide + quinoline system at elevated temperatures and pressures. J. Chem. Eng. Data, 1981. 26(3): p. 307-9.
  • Sebastian, H.M., H.M. Lin, and K.C. Chao, Correlation of solubility of hydrogen in hydrocarbon solvents. AIChE J., 1981. 27(1): p. 138-48.
  • Sebastian, H. M., Simnick, J. J., Lin, H. M., Chao, K.-C., Vapor-Liquid Equilibrium in Binary Mixtures of Carbon Dioxide + n-Decane and Carbon Dioxide + n-Hexadecane,J. Chem. Eng. Data, 1980, 25: p. 138-40.
  • Seiffert, W.-D., Measurement of the scattering cross sections of liquid and solid hydrogen, deuterium and deuterium hydride for thermal neutrons (in German). 1970: Comm. Eur. Communities, Rep. EUR 4455 d, 39 pp.
  • Seiffert, W.D., B. Weckermann, and R. Misenta, Measurement of scattering cross sections of solid hydrogen, deuterium and deuterium hydride for thermal neutrons (in German). Z. Naturforsch., 1970. 25A(6): p. 967-72.
  • Sellers, E.S. and D.R. Augood, The distillation characteristics of liquid hydrogen. Trans. Inst. Chem. Eng., 1956. 34: p. 53-75.
  • Selwood, P.W., The effect of a weak magnetic field on the rare earth catalyzed parahydrogen conversion rate. J. Catal., 1971. 22(1): p. 123-9.
  • Semack, M.G., et al., NMR spin-echo responses in the ordered cubic phase of solid deuterium. Phys. Rev. B, 1978. 18(11): p. 6014-21.
  • Semenchenko, V.K. and K.M. Badra, Thermodynamic stability of crystalline deuterium (in Russian). Zh. Fiz. Khim., 1971. 45(3): p. 685-7.
  • Sen, A., R.D.G. Prasad, and S.P. Reddy, Quadropolar double transitions S(1)(J)+S(0)(J) in the infrared fundamental band of molecular hydrogen at 77 K. J. Chem. Phys., 1980. 72(3): p. 1716-21.
  • Serdyuk, L.S., Study of the thermodynamic properties of parahydrogen and normal hydrogen in a wide range of variation of parameters (in Russian). Kholod. Tekh. Tekhnol., 1968. 7: p. 10-7.
  • Serdyuk, L.S., Equation of state and thermodynamic properties of equilibrium mixtures of o- and p- modifications of hydrogen (in Russian). Zh. Fiz. Khim., 1969. 43(2): p. 485-8.
  • Serdyuk, L.S., Thermal properties of normal hydrogen in conditions of saturation and solidification (in Russian). Zh. Fiz. Khim., 1969. 43(2): p. 488-91.
  • Serdyuk, L.S., Thermodynamic properties of normal hydrogen at temperatures up to 1500 degrees K and pressures up to 5000 bar (in Russian). Teplofiz. Svoistva Veshchestv Mater., 1973. 6: p. 3-15.
  • Serdyuk, L.S., Thermodynamic properties of parahydrogen up to 1500 degrees K and 5000 bars. Thermophys. Prop. Matter Subst., 1974. 2: p. 52-64.
  • Settle, J. L., Greenberg, E., Hubbard, W. N., O'Hare, P. A. G., The Standard Molar Enthalpy of Formation of Liquid Hydrogen Fluoride .DELTA.fH.degree.m(HF, l) at the Temperature 298.15 K Determined by Direct Combination of the Elements in a Fluorine-Bomb Calorimete, J. Chem. Thermodyn., 1994, 26: p. 435-448.
  • Seward, T.M. and E.U. Franck, The system hydrogen - water up to 440 degrees C and 2500 bar pressure. Ber. Bunsenges. Phys. Chem., 1981. 85(1): p. 2-7.
  • Seward, T.M. and E.U. Franck, The System Hydrogen-Water up to 440ø C and 2500 bar Pressure. Ber. Bunsenges. Phys. Chem., 1981. 85: p. 2-7.
  • Shaffer, A. and J. Rousseau, Thermodynamic properties of 20.4 degrees K-equilibrium hydrogen. 1961: Garrett Corp., Los Angeles, Calif., Rep. ASD TR 61-360, 71 pp.
  • Shaievitz, S., Cryogenic production of ultra-pure hydrogen. Philips Tech. Rev., 1965. 26(1): p. 27-31.
  • Sharevskii, B.A. and A.D. Shvets, Characteristics of hydrogen condensation pumps. Sov. Phys. - Tech. Phys. (Engl. Transl.), 1970. 15(3): p. 453-6.
  • Sharma, S.K., H.K. Mao, and P.M. Bell, Raman measurements of hydrogen in the pressure range 0.2-630 kbar at room temperature. Phys. Rev. Lett., 1980. 44(13): p. 886-8.
  • Shashkov, A.G., F.P. Kamchatov, and T.N. Abramenko, Thermal conductivity of the hydrogen-helium mixture. J. Eng. Phys. (Engl. Transl.), 1973. 24(4): p. 461-4.
  • Shashkov, A.G. and T.N. Abramenko, Allowance for the influence of quantum effects on the thermal conductivity of light gases (helium-3, helium-4, hydrogen) (in Russian). Inzh.-Fiz. Zh., 1977. 33(5): p. 843-7.
  • Shaw, H.R. and D.R. Wones, Fugacity coefficients for hydrogen gas between 0 degrees and 1000 degrees C, for pressures to 3000 atm. Am. J. Sci., 1964. 262: p. 918-29.
  • Shaw, J.M., A correlation for hydrogen solubility in alicyclic and aromatic solvents. Can. J. Chem. Eng., 1987. 65(2): p. 293-8.
  • Sherif, I.I., The thermal conductivity of hydrogen between 90 degrees and 280 degrees K. Appl. Sci. Res., Sect. A, 1965. 14(5): p. 353-60.
  • Sherman, R.H., et al., Equations of state of liquid and gaseous normal hydrogen and the application of multiple regression techniques to curve fitting. 1959: Los Alamos Sci. Lab., Rep. LAMS-2357, 32 pp.
  • Shevchenko, S.I., On the possibility of surface superfluidity in para-hydrogen crystals (in Russian). Fiz. Nizk. Temp., 1985. 11(6): p. 660-4.
  • Shiau, J. F., Ziegler, W. T., Gas-liquid phase equilibria in the h(2) + cf(4) at 95-165 k and h(2) + ccif(3) at 135-220 k systems at pressures of 20-120 atm -120 atm, J. Chem. Eng. Data, 1980, 25: p. 239-46.
  • Shields, M.C., A determination of the ratio of the specific heats of hydrogen at 18 degrees C. and -190 degrees C. Phys. Rev., 1917. 10(5): p. 525-40.
  • Shimamura, H. and K. Takayanagi, Rotational transitions in para-hydrogen by molecular collisions. 1971: Rep. - Univ. Tokyo, Inst. Space Aeronaut. Sci., Rep. 470:327-41.
  • Shimizu, H. and T. Kumazawa, Equation of state for fluid hydrogen-isotopes H(2), D(2), and T(2) up to their freezing points at 300 K. J. Chem. Phys., 1983. 78(7): p. 4632-6.
  • Sholander, A.M. and H.B. Nudelman, P-rho-T relationships of low pressure helium-hydrogen mixtures at cryogenic temperatures. Adv. Cryog. Eng., 1967. 12: p. 719-29.
  • Sholander, A.M. and H.B. Nudelman, P-rho-T Relationships of Low Pressure Helium-Hydrogen Mixtures at Cryogenic Temperatures. Adv. Cryo. Eng., 1974. 12: p. 719-729.
  • Shpilrain, E.E. and A.Y. Polishchuk, Thermal-Conductivity and Viscosity of Gaseous Lithium-Hydrogen Mixture. High Temperature, 1980. 18(2): p. 229-233.
  • Shtekkel, F.A. and N.M. Tsin, Determination of the liquid-vapor composition diagram of the methane-nitrogen-hydrogen system (in Russian). Zh. Khim. Promsti., 1939. 16(8): p. 24-8.
  • Sidorov, I. P., Kazarnovskii, Y. S., Goldman, A. M., Solubility of water in compressed gases, Tr. GIAP, 1952, No. 1,48-67.
  • Siegwarth, J.D. and R.O. Voth, A miniature cryogenic high vacuum valve. Adv. Cryo. Eng., 1988. 33: p. 1153-1159.
    Siegwarth, J.D., R.O. Voth, and S.M. Snyder, Liquid-vapour surface sensors for liquid nitrogen and hydrogen. Cryogenics, 1992. 32(2): p. 236-242.
  • Siegwarth, J.D., R.O. Voth, and S.M. Snyder, Resistive Liquid-vapor surface sensors for liquid nitrogen and hydrogen. Journal of Research of the National Institute of Standards and Technology, 1992. 97(5): p. 563-577.
  • Siegwarth, J.D., et al., Thermal hydraulic tests of a liquid hydrogen cold neutron source. 1994, NIST, NISTIR 5026: Boulder CO.
  • Siev, R. and S.K. Yoder, Hydrogen mass flowmeter development. 1961: Aerojet-Gen. Corp., Final Rep. 2048, 236 pp.
  • Sievers, U., Schulz, S., Correlation of the thermodynamic properties of the ideal gases argon,carbon monoxide,hydrogen,nitrogen,oxygen,carbon dioxide,water,methane,and ethylene, Chem.-Ing.-Tech., 1981, 53: p. 459.
  • Sieverts, A., G. Zapf, and H. Moritz, The solubility of hydrogen, deuterium and nitrogen in iron (in German). Z. Phys. Chem., 1938. 183A(1): p. 19-37.
  • Sigel, R., H. Krause, and S. Witkowski, Production of thin solid-hydrogen foils for use as targets in high vacuum. J. Sci. Instrum., 1969. 2(2): p. 187-90.
  • Silvera, I.F., W.N. Hardy, and J.P. McTague, Direct observation of isolated J=1 pairs in solid deuterium and hydrogen by Raman scattering. Phys. Rev. B, 1971. 4(8): p. 2724-33.
  • Silvera, I.F., A. Driessen, and J.A. de Waal, The equation of state of solid molecular hydrogen and deuterium. Phys. Lett. A, 1978. 68(2): p. 207-10.
  • Silvera, I.F. and R. Jochemsen, Orientational ordering in solid hydrogen. Dependence of critical temperature and concentration on density. Phys. Rev. Lett., 1979. 43(5): p. 377-80.
  • Silvera, I.F. and J.T.M. Walraven, Direct determination of the temperature and density of gaseous atomic hydrogen at low temperature by atomic beam techniques. Phys. Lett. A, 1979. 74(3/4): p. 193-6.
  • Silvera, I.F., The solid molecular hydrogens in the condensed phase: fundamentals and static properties. Rev. Mod. Phys., 1980. 52(2): p. 393-452.
  • Silvera, I.F. and J.T.M. Walraven, Stabilization of atomic hydrogen at low temperature. Phys. Rev. Lett., 1980. 44(3): p. 164-8.
  • Silvestrov, V.V. and V.M. Titov, Convergent shock wave in liquid hydrogen. Combust., Explos. Shock Waves (Engl. Transl.), 1975. 11(4): p. 556-8.
  • Simmons, J.A., R.D. Gift, and M. Markels, Jr., Investigation of the effects of vacuum on liquid hydrogen and other cryogens used on launch vehicles. 1964: Atlantic Res. Corp., Final Summ., 329 pp.
  • Simnick, J.J., et al., Vapor-liquid equilibrium of hydrogen/tetralin system at elevated temperatures and pressures. AIChE J., 1977. 23(4): p. 469-76.
  • Simnick, J.J., et al., Solubility of hydrogen in toluene at elevated temperatures and pressures. J. Chem. Eng. Data, 1978. 23(4): p. 339-40.
  • Simnick, J.J., et al., Vapor-liquid phase equilibria in the ternary system hydrogen + methane + tetralin. J. Chem. Eng. Data, 1980. 25(2): p. 147-9.
  • Simon, F., The chemical constants of hydrogen (in German). Z. Phys., 1923. 15: p. 307-11.
  • Simon, F. and F. Lange, The thermal data of condensed hydrogen (in German). Z. Phys., 1923. 15: p. 312-21.
  • Simon, F., K. Mendelssohn, and M. Ruhemann, Anomalous specific heat of solid hydrogen at helium temperatures (in German). Naturwissenschaften, 1930. 18(2): p. 34-5.
  • Simon, F., M. Ruhemann, and W.A.M. Edwards, The melting curves of hydrogen, neon, nitrogen and argon (in German). Z. Phys. Chem., 1930. 6B(5): p. 331-42.
  • Simon, F., M. Ruhemann, and W.A.M. Edwards, The melting curves of hydrogen, neon, nitrogen and argon. (Correction) (in German). Z. Phys. Chem., 1930. 7B(1): p. 80.
  • Simon, H.A., C.S. Liu, and J.P. Hartnett, Properties of hydrogen:nitrogen, hydrogen:carbon-dioxide, and carbon-dioxide:nitrogen mixtures. 1966: NASA Contr. Rep., (NASA-CR-387), 136 pp.
  • Simpson, C.J.S.M., P.D. Gait, and J.M. Simmie. Vibration-rotation energy exchange in carbon dioxide-hydrogen mixtures. II. in Proc. R. Soc. London, Ser. A. 1976.
  • Sindt, C.F. and D.B. Mann, Temperature-Entropy Diagram for Parahydrogen Triple-Point Region. NBS Technical Note 343, 1966.
  • Sindt, C., A Summary of the Characterization Study of Slush Hydrogen. Cryogenics, 1970. 10(10): p. 372-380.
  • Singh, Y. and K.K. Datta, Quantum corrections for the noncentral intermolecular forces to the second virial coefficient of deuterium gas. J. Chem. Phys., 1970. 53(3): p. 1184-8.
  • Singh, S.P. and P.K. Mukhopadhyay, Computation of vapor liquid equilibria for hydrogen and light hydrocarbon systems. AIChE J., 1972. 18(6): p. 1171-6.
  • Singh, S.P. and P.K. Mukhopadhyay, Errata. Computation of vapor liquid equilibria for hydrogen and light hydrocarbon systems, AIChE J., 18, 1171 (1972). AIChE J., 1974. 20(6): p. 1236+1246.
  • Sister, G.A. and P.P. Sokolov, Obtaining technical hydrogen from coke-oven gas at low temperatures. 1963: U.S. Dep. Commer., Off. Tech. Serv., Transl. 63-24285, 5 pp.
  • Skalafuris, A.J., Density quantization of metallic hydrogen. Int. J. Theor. Phys., 1974. 10(1): p. 1-17.
  • Skripka, V.G., Virial coefficients of inert and associated gases in the low temperature region. Second virial coefficients of oxygen, nitrogen, argon, helium, neon, hydrogen, deuterium and krypton at temperatures below 150 degrees K (in Russian). Tr. Vses. Nauchno-Issled. Inst. Kislorodn. Mashinostr., 1965(10): p. 163-83.
  • Slabey, V.A., Hydrogenation of spiropentane. J. Am. Chem. Soc., 1947. 69: p. 475.
  • Slack, M. and A. Grillo, Investigation of hydrogen-air ignition sensitized by nitric oxide and by nitrogen dioxide. 1977: NASA Contr. Rep., (NASA-CR-2896), 43 pp.
  • Slattery, W.L. and W.B. Hubbard, Thermodynamics of a solar mixture of molecular hydrogen and helium at high pressure. Icarus, 1976. 29(2): p. 187-92.
  • Slieker, C.J.G., Thermal diffusion in isotopic hydrogen and hydrogen-helium mixtures. II. Experimental measurements. Physica (Amsterdam), 1965. 31: p. 1388-404.
  • Sluijter, C.G. and R.M. Jonkman, Sound absorption measurements in para hydrogen at 170 degrees K. Physica, 1964. 30(8): p. 1670-2.
  • Sluijter, C.G., H.F.P. Knaap, and J.J.M. Beenakker, Determination of rotational relaxation times of hydrogen isotopes by sound absorption measurements at low temperatures. I. Commun. Kamerlingh Onnes Lab. Univ. Leiden, 1964(337C): p. 1-18.
  • Slyusar, V.P. and N.S. Rudneko, Viscosity of hydrogen deuteride at constant density in the temperature range 20.4-300 degrees K (in Russian). Ukr. Fiz. Zh., 1969. 14(11): p. 1913-5.
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