Calculation of high-order virial coefficients for the square-well potential

Do, Hainam; Feng, Chao; Schultz, Andrew J.; Kofke, David A.; Wheatley, Richard J.

doi:10.1103/physreve.94.013301

Cited by 9 publications

(4 citation statements)

References 30 publications

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“…At the moment, there is no realistic statistical model (which includes intermolecular attraction as well as repulsion) with the completely known set of cluster integrals. Some truncated sets of irreducible integrals (virial coefficients) have been calculated for widely used interaction models (such as the Lennard-Jones model [20,24], its modifications [21,22], Morse [23] and square-well [27] potentials, etc.). There are also a number of approximations for infinite virial sets [14,23,28].…”

Section: Phenomenological Ansatz For the Volume-dependencementioning

confidence: 99%

Equation of state for all regimes of a fluid: From gas to liquid

Ushcats

Bulavin

et al. 2018

Phys. Rev. E

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The study of Mayer's cluster expansion (CE) for the partition function demonstrates a possible way to resolve the problem of the CE non-physical behavior at condensed states of fluids. In particular, a general equation of state is derived for finite closed systems of interacting particles, where the pressure is expressed directly in terms of the density (or system volume) and temperature-volume dependent reducible cluster integrals. Although its accuracy is now greatly affected by the limited character of the existing data on the reducible cluster integrals and, especially, the absence of any information on their density dependence, a number of simple approximations indicate the qualitative adequacy of this equation in various regimes of a fluid: from gaseous to liquid states (including the transition region).

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Section: Phenomenological Ansatz For the Volume-dependencementioning

confidence: 99%

Equation of state for all regimes of a fluid: From gas to liquid

Ushcats

Bulavin

et al. 2018

Phys. Rev. E

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“…Recent studies of Mayer's cluster expansion [9] for the partition function of realistic interaction models (i.e., the models that include intermolecular attraction as well as repulsion: the Lennard-Jones model [10,11] and its modifications [12,13], square-well [14], Morse [15], Yukawa [16] potentials, etc.) have renewed interest to the problem.…”

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confidence: 99%

Evidence for a first-order phase transition at the divergence region of activity expansions

2018

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On the example of a lattice-gas model, a convincing confirmation is obtained for the direct relationship between the condensation phenomenon and divergent behavior of the virial expansions for pressure and density in powers of activity. The present study analytically proves the pressure equality for the low-density and high-density virial expansions in powers of density (in terms of irreducible cluster integrals or virial coefficients) exactly at the symmetrical points, where their isothermal bulk modulus vanishes, as well as for the corresponding expansions in powers of activity (in terms of reducible cluster integrals) at the same points (the points of their divergence). For lattice-gas models of arbitrary geometry and dimensions, a simple and general expression is derived for the phase-transition activity (the convergence radius of activity expansions) that, in particular, exactly matches the well-known phase-transition activity of the Lee -Yang model. In addition, the study demonstrates that Mayer's expansion with the constant (volume independent) cluster integrals remains correct up to the condensation beginning, and the actual density-dependence may be taken into account for the high-order integrals only in more dense regimes beyond the saturation point.

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“…Rather than direct evaluation of the sum as suggested in Equation ), a more efficient recursive algorithm due to Wheatley 15 is available to compute the integrand, f B . This algorithm can be modified to evaluate temperature derivatives of virial coefficients in the same Mayer‐sampling calculation 5 .…”

Section: Models and Methodsmentioning

confidence: 99%

Properties of supercritical N₂, O₂, CO₂, and NH₃ mixtures from the virial equation of state

2020

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We report virial coefficients up to sixth order in density for N 2 , O 2 , NH 3 , and CO 2 , covering temperatures from 50 to 1,000 K. The reported values include coefficients and their first three temperature derivatives, for the pure species as well as all of those needed to evaluate full composition dependence of mixtures formed from any or all of these compounds. The values are obtained by calculation of appropriate cluster integrals using Mayer sampling Monte Carlo, with intermolecular interactions described by the Transferable Potential for Phase Equilibria (TraPPE) force field. All coefficients are fit as a function of temperature, yielding a thermodynamic model with analytic dependence on temperature, density, and composition. The coefficients and properties computed from them are compared to experimental data where available.

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Calculation of high-order virial coefficients for the square-well potential

Cited by 9 publications

References 30 publications

Equation of state for all regimes of a fluid: From gas to liquid

Equation of state for all regimes of a fluid: From gas to liquid

Evidence for a first-order phase transition at the divergence region of activity expansions

Properties of supercritical N₂, O₂, CO₂, and NH₃ mixtures from the virial equation of state

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Calculation of high-order virial coefficients for the square-well potential

Cited by 9 publications

References 30 publications

Equation of state for all regimes of a fluid: From gas to liquid

Equation of state for all regimes of a fluid: From gas to liquid

Evidence for a first-order phase transition at the divergence region of activity expansions

Properties of supercritical N2, O2, CO2, and NH3 mixtures from the virial equation of state

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Product

Resources

About

Properties of supercritical N₂, O₂, CO₂, and NH₃ mixtures from the virial equation of state