Accurate and Transferable Pauli Exchange-Repulsion for Molecules with the Anisotropic Valence Density Overlap Model
Abstract
Pauli exchange-repulsion is the dominant short-range intermolecular interaction and it is an essential component of molecular force fields. Current approaches to modeling Pauli repulsion in molecular force fields often rely on over 20 atom types to achieve chemical accuracy. The number of parameters in these approaches hampers the development of force fields with quantum-chemical accuracy that are transferable across many chemical systems. We present the anisotropic valence density overlap (AVDO) model for exchange-repulsion. The model produces sub-kcal/mol accuracy for dimers of organic molecules from the S101x7 dataset, a representative set of the most common biologically relevant intermolecular interactions, and for acene dimers of increasing size. It uses a single universal parameter, related to an atomic cross-sectional area, that is transferable across chemical systems. Given recent progress in machine learning the electronic density, this model offers a promising path toward high-accuracy, next-generation machine-learned force fields.