Non-adiabaticity from first principles: the exact-factorization approach for solids
Abstract
The thorough treatment of electron-lattice interactions from first principles is one of the main goals in condensed matter physics. While the commonly applied adiabatic Born-Oppenheimer approximation is sufficient for describing many physical phenomena, it is limited in its ability to capture meaningful features originating from non-adiabatic coupling effects. The exact factorization method, starting from the full Hamiltonian of electrons and nuclei, provides a way to systematically account for non-adiabatic effects. This formalism was recently developed into an ab initio density functional theory framework. Within this framework we here develop a perturbative approach to the electronic states in solid state materials. We derive exact-factorization-based perturbations of the Kohn-Sham states up to second order in the nuclear displacements. These non-adiabatic features in the calculated energy and wavefunction corrections are expressed in terms of readily available density functional perturbation theory components.
Cite
@article{arxiv.2502.07439,
title = {Non-adiabaticity from first principles: the exact-factorization approach for solids},
author = {Galit Cohen and Rachel Steinitz-Eliyahu and E. K. U. Gross and Sivan Refaely-Abramson and Ryan Requist},
journal= {arXiv preprint arXiv:2502.07439},
year = {2025}
}