Calculation of the Thermodynamic Properties of Methane up to 30 MPa Using a New Equation of State with Regular and Scale Parts and Few Constants

The heat capacities , C p and speed of sound W of methane were calculated by a new equation of state with few adjustable constants. The equation includes a new regular part with 13 coefficients and a scale part with 6 coefficients with a regular crossover function containing two fitting parameters....

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Bibliographic Details
Published in:High temperature 2023-06, Vol.61 (3), p.328-338
Main Authors: Bezverkhii, P. P., Dutova, O. S.
Format: Article
Language:English
Subjects:
Atoms and Molecules in Strong Fields
Classical and Continuum Physics
Constants
Crossovers
Equations of state
Ideal gas
Industrial Chemistry/Chemical Engineering
Ising model
Laser Matter Interaction
Liquid-vapor equilibrium
Materials Science
Methane
Physical Chemistry
Physics
Physics and Astronomy
Specific heat
Thermodynamic properties
Thermophysical Properties of Materials
Three dimensional models
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Summary:The heat capacities , C p and speed of sound W of methane were calculated by a new equation of state with few adjustable constants. The equation includes a new regular part with 13 coefficients and a scale part with 6 coefficients with a regular crossover function containing two fitting parameters. The constants in the equation of state were determined using only ( p , ρ, T ) data for СH 4 ; no data on , C p , and W were employed, except for the data on isochoric heat capacity in the ideal-gas state and value of at 100 K on the liquid branch on the liquid–vapor equilibrium curve. The calculated values of , C p , and W are close to the experimental and tabulated values in the regular region. Calculations in the critical region uses universal critical indices α, β, γ according to the three-dimensional Ising model. A discrepancy with the tabulated data is caused by application of the scaling equation of state. The calculated values are compared with the predictions by the known crossover equations of state for СH 4 . The root-mean-square error in the description of СH 4 pressure is σ р = 0.5%, the mean absolute deviation is 0.3%, the uncertainty in does not exceed 5%.
ISSN:0018-151X
1608-3156
DOI:10.1134/S0018151X23020037