English

Efficient implementation of the GW approximation within the all-electron FLAPW method

Materials Science 2010-11-15 v2

Abstract

We present an implementation of the GW approximation for the electronic self-energy within the full-potential linearized augmented-plane-wave (FLAPW) method. The algorithm uses an all-electron mixed product basis for the representation of response matrices and related quantities. This basis is derived from the FLAPW basis and is exact for wave-function products. The singularity of the bare and screened interaction potentials gives rise to a numerically important self-energy contribution, which we treat analytically to achieve good convergence with respect to the k-point sampling. As numerical realizations of the GW approximation typically suffer from the high computational expense required for the evaluation of the nonlocal and frequency-dependent self-energy, we demonstrate how the algorithm can be made very efficient by exploiting spatial and time-reversal symmetry as well as by applying an optimization of the mixed product basis that retains only the numerically important contributions of the electron-electron interaction. Furthermore, we demonstrate that one can employ an extrapolar approximation for high-lying states to reduce the number of empty states that must be taken into account explicitly in the construction of the polarization function and the self-energy. We show convergence tests, CPU timings, and results for prototype semiconductors and insulators as well as ferromagnetic nickel.

Keywords

Cite

@article{arxiv.1003.0316,
  title  = {Efficient implementation of the GW approximation within the all-electron FLAPW method},
  author = {Christoph Friedrich and Stefan Blügel and Arno Schindlmayr},
  journal= {arXiv preprint arXiv:1003.0316},
  year   = {2010}
}
R2 v1 2026-06-21T14:52:22.224Z