Xenon thermodynamic propertie

V. A. Rabinovich, A. A. Vasserman, V. I. Nedostup, and I. S. Veksler, Thermodynamic Properties of Neon, Argon, Krypton and Xenon, Springer, Berlin, 1988. 

L. V. Gurvich, I. V. Veyts, and C. B. Alcock, Thermodynamic Properties of Individual Substances, Vol. 1 Elements Oxygen, Hydrogen (Deuterium, Tritium), Fluorine, Chlorine, Bromine, Iodine, Helium, Neon, Argon, Krypton, Xenon, Radon, Sulfur, Nitrogen, Phosphorus, and Their Compounds, Pt. 1 Methods and Computation, Hemisphere, New York, 1989. 

The values in these tables were generated from the NIST REFPROP software (Lemmon, E. W, McLinden, M. O., and Huber, M. L., NIST Standard Reference Database 23 Reference Fluid Thermodynamic and Transport Properties—REFPROP, National Institute of Standards and Technology, Standard Reference Data Program, Gaithersburg, Md., 2002, Version 7.1). The primary source for the thermodynamic properties is Lemmon, E. W, and Span, R., Short Fundamental Equations of State for 20 Industrial Fluids, / Chem. Eng. Data 51(3) 785-850, 2006. The source for viscosity and thermal conductivity is McCarty, R. D., Correlations for the Thermophysical Properties of Xenon, National Institute of Standards and Technology, Boulder, Colo., 1989. 

Values extracted and in some cases rounded off from those cited in Rabinovich (ed.), Thermophysical Properties of Neon, At on, Krypton and Xenon, Standards Press, Moscow, 1976. v = specific volume, mVkg h = specific enthalpy, kj/kg s = specific entropy, kJ/(kg-K). This source contains an exhaustive tabulation of values. The notation 7.420.-4 signifies 7.420 x 10". This book was published in English translation by Hemisphere, New York, 1988 (604 pp.). The 1993 ASHRAE Handbook—Fundamentals (SI ed.) has a thermodynamic chart for pressures from 1 to 2000 bar, temperatures from 90 to 700 K. Saturation and superheat tables and a chart to 50,000 psia, 1220 R appear in Stewart, R. B., R. T. Jacobsen, et al.. Thermodynamic Properties of Refrigerants, ASHRAE, Atlanta, GA, 1986 (521 pp.). For specific heat, thermal conductivity, and viscosity see Thermophysical Properties of Refrigerants, ASHRAE, 1993. 

Studies of how the intensities of bands vary as a function of concentration or pressure have been important in determining the identities of reaction products (e.g. Xc2 from XeF" and elemental xenon (Section 12.2.2)). Variations as a function of temperature have been used to estimate the enthalpy changes of various reactions, such as the dissociation of digallane (Ga2Hs) into two monogaUane molecules (GaHa) [17]. An alternative approach has been to trap vapors of equilibrium mixtures of molecules with different conformations or different structures held at different temperatures in cold matrices (Section 2.8.1). Data from IR spectra have then been used to determine equilibrium constants and associated thermodynamic properties for systems such as ds-FC(0)0F trani-FC(0)OF [18]. 

Yaws, C. 2001. Matheson Gas Data Book, 7th ed. Parsippany, NJ Matheson TriGas New York McGraw-Hill. The Matheson Gas Data Book contains individnal sections with property data on over 150 indnstrial gaseons elements and componnds (from acetylene to xenon). Data include, thermodynamic properties, IR spectra, vapor pressnre-temperature curves, Henry s Law constants, explosion limits, and viscosity. 

Juza, J. Sifner, O. (1977). Modified equation of state and formulation of thermodynamic properties of xenon in the range from 161.36 to 800 K and 0 to 350 MPa. Acta Tech. CSAV, 22, 1-32. 

Two interesting developments have emerged from Ferguson s work. Helium at one atmosphere pressure has a thermodynamic activity of 0.01, which on comparison with Table 5.2, suggests that it should be suitable as a general anaesthetic. Helium does in fact have general anaesthetic properties, and xenon has subse-... 

The National Institute of Standards and Technology has created an on-line database to provide pure component thermodynamic and transport properties. The on-line database returns transport properties based on input temperature and pressure. The on-line database extends to 1500 K for helium and 800 K for xenon. Tabular pure component viscosity and thermal conductivity data obtained from the on-line database were used directly in the mixture property correlations. Tabular data from NIST can be accessed from http /AVebBook.nist.gov or a more advanced version can be purchased. 

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