English

Machine-learning free-energy functionals using density profiles from simulations

Soft Condensed Matter 2021-03-23 v2 Chemical Physics

Abstract

The formally exact framework of equilibrium Density Functional Theory (DFT) is capable of simultaneously and consistently describing thermodynamic and structural properties of interacting many-body systems in arbitrary external potentials. In practice, however, DFT hinges on approximate (free-)energy functionals from which density profiles (and hence the thermodynamic potential) follow via an Euler-Lagrange equation. Here we explore a relatively simple Machine Learning (ML) approach to improve the standard mean-field approximation of the excess Helmholtz free energy functional of a 3D Lennard-Jones system at a supercritical temperature. The learning set consists of density profiles from grand-canonical Monte Carlo simulations of this system at varying chemical potentials and external potentials in a planar geometry only. Using the DFT formalism we nevertheless can extract not only very accurate 3D bulk equations of state but also radial distribution functions using the Percus test-particle method. Unfortunately, our ML approach did not provide very reliable Ornstein-Zernike direct correlation functions for small distances.

Keywords

Cite

@article{arxiv.2101.01942,
  title  = {Machine-learning free-energy functionals using density profiles from simulations},
  author = {Peter Cats and Sander Kuipers and Sacha de Wind and Robin van Damme and Gabriele M. Coli and Marjolein Dijkstra and René van Roij},
  journal= {arXiv preprint arXiv:2101.01942},
  year   = {2021}
}

Comments

12 pages, 10 figures

R2 v1 2026-06-23T21:49:54.175Z