scholarly journals Entropy Pair Functional Theory: Direct Entropy Evaluation Spanning Phase Transitions

Entropy ◽  
2021 ◽  
Vol 23 (2) ◽  
pp. 234
Author(s):  
Donald M. Nicholson ◽  
C. Y. Gao ◽  
Marshall T. McDonnell ◽  
Clifton C. Sluss ◽  
David J. Keffer
Keyword(s):  
Free Energy ◽  
Correlation Function ◽  
Pair Correlation Function ◽  
Excess Entropy ◽  
Pair Correlation ◽  
Pair Potential ◽  
Thermodynamic Integration ◽  
First Principles Calculation ◽  
Simple Modification ◽  
Single Temperature

We prove that, within the class of pair potential Hamiltonians, the excess entropy is a universal, temperature-independent functional of the density and pair correlation function. This result extends Henderson’s theorem, which states that the free energy is a temperature dependent functional of the density and pair correlation. The stationarity and concavity of the excess entropy functional are discussed and related to the Gibbs–Bugoliubov inequality and to the free energy. We apply the Kirkwood approximation, which is commonly used for fluids, to both fluids and solids. Approximate excess entropy functionals are developed and compared to results from thermodynamic integration. The pair functional approach gives the absolute entropy and free energy based on simulation output at a single temperature without thermodynamic integration. We argue that a functional of the type, which is strictly applicable to pair potentials, is also suitable for first principles calculation of free energies from Born–Oppenheimer molecular dynamics performed at a single temperature. This advancement has the potential to reduce the evaluation the free energy to a simple modification to any procedure that evaluates the energy and the pair correlation function.

Perturbation theory of the pair correlation function in molecular fluids

1978 ◽  
Vol 56 (5) ◽  
pp. 571-580 ◽  
Author(s):  
R. L. Henderson ◽  
C. G. Gray
Keyword(s):  
Perturbation Theory ◽  
Correlation Function ◽  
Pair Correlation Function ◽  
Pair Correlation ◽  
Mean Field ◽  
Pair Potential ◽  
Harmonic Series ◽  
Harmonic Space ◽  
Potential Symmetries ◽  
Harmonic Components

We study the perturbation theory of the angular pair correlation function g(rω1ω2)in a molecular fluid. We consider an anisotropic pair potential of the form u = u0 + ua, where u0 is an isotropic 'reference' potential, and for simplicity in this paper we assume the perturbation potential ua to be 'multipole-like', i.e., to contain no l = 0 spherical harmonics. We expand g in powers of ua about g0, the radial distribution function appropriate to u0. This series is examined by expanding ha = h−h0 (where h = g−1) and its corresponding direct correlation function ca in spherical harmonic components. We consider approximate summations of the series in ua that automatically truncate the corresponding harmonic series, so that the Ornstein–Zernike (OZ) equation relating ha and ca can be solved in closed form. We first expand ca = c1 + c2 + … where cn includes all terms in ca of order (ua)n. Taking ua to be a quadrupole–quadrupole interaction, we find that a 'mean field' (MF) approximation ca = c1 gives rise to only three nonvanishing harmonic components in ha, so that OZ is solved explicitly in Fourier space. The MF solution for multipoles of general order is given in an appendix. Graphical methods are then used to identify the class of all terms in the ua series that are restricted to the harmonic space defined by MF. A portion of this class can be summed by solving OZ with the closure ca = −βg0ua + h0(ha−ca), where β = (kT)−1, h0 = g0−1 This system is designated as generalized MF (GMF), and solved by numerical iteration. Numerical results from MF and GMF are presented for quadrupolar ua, taking u0 to be a Lennard-Jones potential. Symmetries imposed by the restricted harmonic space are foreign to the full g, yet harmonics within this space are sufficient for evaluation of many macroscopic properties. The results are therefore evaluated in harmonic form by comparison with the corresponding harmonic components of the 'correct' g as evaluated by Monte Carlo simulation.

Temperature dependence of the pair correlation function in an inhomogeneous liquid: application to C24Cs

1982 ◽  
Vol 60 (8) ◽  
pp. 1139-1144 ◽  
Author(s):  
Michael Plischke ◽  
W. D. Leckie
Keyword(s):  
Correlation Function ◽  
Temperature Dependence ◽  
Pair Correlation Function ◽  
Pair Correlation ◽  
Pair Potential ◽  
Intercalation Compounds ◽  
Effective Pair Potential ◽  
Graphite Intercalation ◽  
Effective Pair ◽  
Graphite Lattice

We study the properties of a model appropriate to stage 2 graphite intercalation compounds such as C24Cs and C24K. The Hamiltonian consists of an effective pair potential for the intercalate and a periodic background potential due to the graphite lattice. We obtain the pair correlation function over the range of temperatures 0–300 K. We find orientational effects and compare our results with data on C24Cs.

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