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The intrinsic Helmholtz free-energy functional, the centerpiece of classical density functional theory (cDFT), is at best only known approximately for 3D systems, which hampers the use of cDFT as a powerful tool for describing the intricate thermodynamic equilibrium properties and structural aspects of classical many-body systems. Here we introduce a method for learning a quasi-exact neural-network approximation of this functional by exclusively training on a dataset of radial distribution functions. This method based on pair-correlation matching circumvents the need to sample costly heterogeneous density profiles in a wide variety of external potentials and hence offers a pathway to significantly ease the computational demands for future approaches to extend machine learning for cDFT to arbitrary three-dimensional systems. For a supercritical 3D Lennard-Jones system we demonstrate that the learned neural free-energy functional accurately predicts planar inhomogeneous density profiles under various complex external potentials obtained from simulations, while simultaneously offering precise thermodynamic predictions far outside the training regime.
Dijkman et al. (Fri,) studied this question.