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Regularized Perturbation Theory for Ab initio Solids

Materials Science 2025-10-28 v1 Chemical Physics Computational Physics

Abstract

Second-order Moller-Plesset perturbation theory (MP2) for ab initio simulations of solids is often limited by divergence or over-correlation issues, particularly in metallic, narrow-gap, and dispersion-stabilized systems. We develop and assess three regularized second-order perturbation theories: κ\kappa-MP2, σ\sigma-MP2, and the size-consistent Brillouin-Wigner approach (BW-s2), across metals, semiconductors, molecular crystals, and rare gas solids. BW-s2 achieves high accuracy for cohesive energies, lattice constants, and bulk moduli in metals, semiconductors, and molecular crystals, rivaling or surpassing coupled-cluster with singles and doubles at lower cost. In rare gas solids, where MP2 already underbinds, κ\kappa-MP2 does not make the results much worse while BW-s2 struggles. These results illustrate both the potential and the limitations of regularized perturbation theory for efficient and accurate solid-state simulations. While broader testing is warranted, BW-s2(α\alpha = 2) appears particularly promising, with possible advantages over modern random-phase approximations and coupled-cluster theory.

Keywords

Cite

@article{arxiv.2508.15744,
  title  = {Regularized Perturbation Theory for Ab initio Solids},
  author = {Meng-Fu Chen and Jinghong Zhang and Hieu Q. Dinh and Adam Rettig and Joonho Lee},
  journal= {arXiv preprint arXiv:2508.15744},
  year   = {2025}
}
R2 v1 2026-07-01T05:00:30.566Z