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DLPNO-MP2 for Periodic Systems using Megacell Embedding

Chemical Physics 2025-07-15 v1 Materials Science Computational Physics

Abstract

We present a domain-based local pair natural orbital M{\o}ller--Plesset second order perturbation theory (DLPNO-MP2) for periodic systems, working within an LCAO formalism within the Tubromole program package. This approach, Megacell-DLPNO-MP2, embeds a supercell correlation treatment within a megacell and does not involve periodic image summation for the Coulomb integrals. Working in a basis of well-localised Wannier functions, periodicity is instead imposed through rigorous translational symmetry of Hamiltonian integrals and wavefunction parameters. The accuracy of the method is validated through comparison with a complementary periodic DLPNO-MP2 method that employs Born--von K{\'a}rm{\'a}n boundary conditions, described in paper I of this series. The PNO approximations are shown to be equivalent in the two approaches and entirely consistent with molecular DLPNO-MP2 calculations. The Megacell-DLPNO-MP2 method displays sub-linear scaling with respect to supercell size at the asymptotic limit and example calculations are presented with up to 15000 basis functions in the correlation treatment.

Keywords

Cite

@article{arxiv.2507.09814,
  title  = {DLPNO-MP2 for Periodic Systems using Megacell Embedding},
  author = {Andrew Zhu and Arman Nejad and Poramas Komonvasee and Kesha Sorathia and David P. Tew},
  journal= {arXiv preprint arXiv:2507.09814},
  year   = {2025}
}
R2 v1 2026-07-01T03:58:55.528Z