English

An efficient implementation of two-component relativistic exact-decoupling methods for large molecules

Chemical Physics 2013-05-10 v2 Materials Science Atomic and Molecular Clusters Computational Physics Quantum Physics

Abstract

We present an efficient algorithm for one- and two-component relativistic exact-decoupling calculations. Spin-orbit coupling is thus taken into account for the evaluation of relativistically transformed (one-electron) Hamiltonian. As the relativistic decoupling transformation has to be evaluated with primitive functions, the construction of the relativistic one-electron Hamiltonian becomes the bottleneck of the whole calculation for large molecules. For the established exact-decoupling protocols, a minimal matrix operation count is established and discussed in detail. Furthermore, we apply our recently developed local DLU scheme [J. Chem. Phys. 136 (2012) 244108] to accelerate this step. With our new implementation two-component relativistic density functional calculations can be performed invoking the resolution-of-identity density-fitting approximation and (Abelian as well as non-Abelian) point group symmetry to accelerate both the exact-decoupling and the two-electron part. The capability of our implementation is illustrated at the example of silver clusters with up to 309 atoms, for which the cohesive energy is calculated and extrapolated to the bulk.

Keywords

Cite

@article{arxiv.1303.4446,
  title  = {An efficient implementation of two-component relativistic exact-decoupling methods for large molecules},
  author = {Daoling Peng and Nils Middendorf and Florian Weigend and Markus Reiher},
  journal= {arXiv preprint arXiv:1303.4446},
  year   = {2013}
}

Comments

53 pages, 1 figure, 9 tables, incl. supp. inf

R2 v1 2026-06-21T23:44:08.218Z