Explicitly correlated plane waves: Accelerating convergence in periodic wavefunction expansions
Abstract
We present an investigation into the use of an explicitly correlated plane wave basis for periodic wavefunction expansions at the level of second-order M{\o}ller-Plesset perturbation theory (MP2). The convergence of the electronic correlation energy with respect to the one-electron basis set is investigated and compared to conventional MP2 theory in a finite homogeneous electron gas model. In addition to the widely used Slater-type geminal correlation factor, we also derive and investigate a novel correlation factor that we term Yukawa-Coulomb. The Yukawa-Coulomb correlation factor is motivated by analytic results for two electrons in a box and allows for a further improved convergence of the correlation energies with respect to the employed basis set. We find the combination of the infinitely delocalized plane waves and local short-ranged geminals provides a complementary, and rapidly convergent basis for the description of periodic wavefunctions. We hope that this approach will expand the scope of discrete wavefunction expansions in periodic systems.
Cite
@article{arxiv.1307.6463,
title = {Explicitly correlated plane waves: Accelerating convergence in periodic wavefunction expansions},
author = {Andreas Grüneis and James J. Shepherd and Ali Alavi and David P. Tew and George H. Booth},
journal= {arXiv preprint arXiv:1307.6463},
year = {2014}
}
Comments
15 pages, 13 figures