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Efficient Hartree-Fock Exchange Algorithm with Coulomb Range Separation and Long-Range Density Fitting

Chemical Physics 2023-09-27 v2

Abstract

Separating the Coulomb potential into short-range and long-range components enables the use of different electron repulsion integral algorithms for each component. The short-range part can be efficiently computed using the analytical algorithm due to the locality in both Gaussian-type orbital basis and the short-range Coulomb potentials. The integrals for the long-range Coulomb potential can be approximated with the density fitting method. A very small auxiliary basis is sufficient for the density fitting method to accurately approximate the long-range integrals. This feature significantly reduces the computational efforts associated with the N4N^4 scaling in density fitting algorithms. For large molecules, the range separation and long-range density fitting method outperforms the conventional analytical integral evaluation scheme employed in Hartree-Fock calculations and provides more than twice the overall performance. Additionally, this method yields higher accuracy compared to regular density fitting methods. The error in the Hartree-Fock energy can be easily reduced to 0.1 μEh\mu E_h per atom, which is significantly more accurate than the typical error of 10 μEh\mu E_h per atom observed in regular density fitting methods.

Keywords

Cite

@article{arxiv.2306.12764,
  title  = {Efficient Hartree-Fock Exchange Algorithm with Coulomb Range Separation and Long-Range Density Fitting},
  author = {Qiming Sun},
  journal= {arXiv preprint arXiv:2306.12764},
  year   = {2023}
}
R2 v1 2026-06-28T11:11:44.235Z