English

Interatomic spin-orbit coupling in atomic orbital-based tight-binding models

Materials Science 2024-07-16 v1

Abstract

Interatomic hopping mediated by spin-orbit coupling (SOC) entangles spin, orbital and sublattice degrees of freedom of electrons, leading to the emergence of intriguing phenomena such as novel topological insulators and exotic spin-dependent transport including chirality-induced spin selectivity (CISS). Despite these effects, a comprehensive microscopic formalism to describe the spin-dependent hopping remains insufficiently established. In this study, we systematically investigate SOC hopping by analytically deriving the hopping integrals within a two-center approximation based on atomic orbitals. Introducing independent parameters, or extended Slater-Koster symbols, that characterize SOC hopping, we explicitly determine the form of the hopping for ss, pp and dd orbitals in the arbitrary hopping directions. Our formalism is then implemented in tight-binding models on several lattices. Furthermore, we examine the effect of SOC on band dispersion by employing a multipole decomposition for the SOC Hamiltonian, providing a fundamental understanding of SOC-induced phenomena. In particular, we derive an explicit expression for the SOC Hamiltonian that causes unique spin splitting in chiral systems by considering a triangular helical chain. Most importantly, the obtained SOC Hamiltonian does not contain a term that has the symmetry of electric toroidal monopole G0G_0 but rather an electric toroidal quadrupole GuG_u, which is the origin of chirality in this case.

Keywords

Cite

@article{arxiv.2407.09951,
  title  = {Interatomic spin-orbit coupling in atomic orbital-based tight-binding models},
  author = {Masaki Kato and Masao Ogata},
  journal= {arXiv preprint arXiv:2407.09951},
  year   = {2024}
}

Comments

21 pages, 9 figures

R2 v1 2026-06-28T17:39:50.906Z