English

Treating geometric phase effects in nonadiabatic dynamics

Chemical Physics 2023-04-18 v2 Materials Science

Abstract

We present an approach for eliminating the gauge freedom for derivative couplings in nonadiabatic dynamics in the presence of geometric phase effects. This approach relies on a bottom-up construction of a parametric quantum Hamiltonian in terms of functions of a dynamical variable, which can be associated with real and imaginary-valued contributions to the Hamiltonian in a given diabatic basis. By minimizing the deviation of the imaginary functions from a constant we identify a set of diabatic bases that recover the real-valued gauge commonly used for topologically-trivial systems. This minimization, however, also confines the gauge freedom in the topologically-nontrivial case, opening a path towards finding gauge-invariant derivative couplings under geometric phase effects. Encouraging results are presented for fewest-switches surface hopping calculations of a nuclear wavepacket traversing a single avoided crossing, for which fully gauge-invariant derivative couplings are found.

Keywords

Cite

@article{arxiv.2206.13539,
  title  = {Treating geometric phase effects in nonadiabatic dynamics},
  author = {Alex Krotz and Roel Tempelaar},
  journal= {arXiv preprint arXiv:2206.13539},
  year   = {2023}
}

Comments

A significant update over the previous version of this theory has been made to address a gauge freedom introduced by the choice of diabatic basis in which a given Hamiltonian is expressed. 13 pages, 3 figures

R2 v1 2026-06-24T12:05:51.233Z