Entropy of simulated liquids using multiscale cell correlation

Hafiz Saqib Ali, Jonathan Higham, Richard Henchman

    Research output: Contribution to journalArticlepeer-review

    Abstract

    Accurately calculating the entropy of liquids is an important goal, given that many processes take place in the liquid phase. Of almost equal importance is understanding the values obtained. However, there are few methods that can calculate the entropy of such systems, and fewer still to make sense of the values obtained. We present our multiscale cell correlation (MCC) method to calculate the entropy of liquids from molecular dynamics simulations. The method uses forces and torques at the molecule and united-atom levels and probability distributions of molecular coordinations and conformations. The main differences with previous work are the consistent treatment of the mean-field cell approximation to the appropriate degrees of freedom, the separation of the force and torque covariance matrices, and the inclusion of conformation correlation for molecules with multiple dihedrals. MCC is applied to a broader set of 56 important industrial liquids modelled using the GAFF and OPLS force fields with 1.14*CM1A charges. Unsigned errors versus experimental entropies are 8.7 J K−1 mol−1 for GAFF and 9.8 J K −1 mol−1 for OPLS. This is significantly better than the 2-Phase Thermodynamics method for the subset of molecules in common, which is the only other method that has been applied to such systems. MCC makes clear why the entropy has the value it does by providing a decomposition in terms of translational and rotational vibrational entropy and topographical entropy at the molecular and united-atom levels.
    Original languageEnglish
    JournalEntropy
    DOIs
    Publication statusPublished - 31 Jul 2019

    Keywords

    • structure
    • thermodynamics
    • probability distribution
    • force
    • torque
    • coordination
    • conformation
    • Molecular dynamics simulation

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