English

Generalized Many-Body Dispersion Correction through Random-phase Approximation for Chemically Accurate Density Functional Theory

Chemical Physics 2023-03-07 v4 Machine Learning

Abstract

We extend our recently proposed Deep Learning-aided many-body dispersion (DNN-MBD) model to quadrupole polarizability (Q) terms using a generalized Random Phase Approximation (RPA) formalism, thus enabling the inclusion of van der Waals contributions beyond dipole. The resulting DNN-MBDQ model only relies on ab initio-derived quantities as the introduced quadrupole polarizabilities are recursively retrieved from dipole ones, in turn modelled via the Tkatchenko-Scheffler method. A transferable and efficient deep-neuronal network (DNN) provides atom in molecule volumes, while a single range-separation parameter is used to couple the model to Density Functional Theory (DFT). Since it can be computed at a negligible cost, the DNN-MBDQ approach can be coupled with DFT functionals such as PBE,PBE0 and B86bPBE (dispersionless). The DNN-MBQ-corrected functionals reach chemical accuracy while exhibiting lower errors compared to their dipole-only counterparts.

Keywords

Cite

@article{arxiv.2210.09784,
  title  = {Generalized Many-Body Dispersion Correction through Random-phase Approximation for Chemically Accurate Density Functional Theory},
  author = {Pier Paolo Poier and Louis Lagardère and Jean-Philip Piquemal},
  journal= {arXiv preprint arXiv:2210.09784},
  year   = {2023}
}
R2 v1 2026-06-28T03:54:29.208Z