English

An Efficient DFT Solver for Nanoscale Simulations and Beyond

Materials Science 2021-05-05 v2 Mesoscale and Nanoscale Physics Chemical Physics Computational Physics Quantum Physics

Abstract

We present the One-orbital Ensemble Self-Consistent Field (OE-SCF) method, an {alternative} orbital-free DFT solver that extends the applicability of DFT to system sizes beyond the nanoscale while retaining the accuracy required to be predictive. OE-SCF is an iterative solver where the (typically computationally expensive) Pauli potential is treated as an external potential and updated after each iteration. Because only up to a dozen iterations are needed to reach convergence, OE-SCF dramatically outperforms current orbital-free DFT solvers. Employing merely a single CPU, we carried out the largest ab initio simulation for silicon-based materials to date. OE-SCF is able to converge the energy of bulk-cut Si nanoparticles as a function of their diameter up to 16 nm, for the first time reproducing known empirical results. We model polarization and interface charge transfer when a Si slab is sandwiched between two metal slabs where lattice matching mandates a very large slab size. Additionally, OE-SCF opens the door to adopt even more accurate functionals in orbital-free DFT simulations while still tackling systems sizes beyond the nanoscale.

Keywords

Cite

@article{arxiv.2010.07385,
  title  = {An Efficient DFT Solver for Nanoscale Simulations and Beyond},
  author = {Xuecheng Shao and Wenhui Mi and Michele Pavanello},
  journal= {arXiv preprint arXiv:2010.07385},
  year   = {2021}
}
R2 v1 2026-06-23T19:21:34.438Z