Effect of Electron-Electron Interactions on Rashba-like and Spin-Split Systems

Abstract

The role of electron-electron interactions is analyzed for Rashba-like and spin-split systems within a tight-binding single-band Hubbard model with on-site and all nearest-neighbor matrix elements of the Coulomb interaction. By Rashba-like systems we refer to the Dresselhaus and Rashba spin-orbit coupled phases; spin-split systems have spin-up and spin-down Fermi surfaces shifted relative to each other. Both systems break parity but preserve time-reversal symmetry. They belong to a class of symmetry-breaking ground states that satisfy: (i) electron crystal momentum is a good quantum number (ii) these states have no net magnetic moment and (iii) their distribution of `polarized spin' in momentum space breaks the lattice symmetry. In this class, the relevant Coulomb matrix elements are found to be nearest-neighbor exchange J, pair-hopping J' and nearest-neighbor repulsion V. These ground states lower their energy most effectively through J, hence we name them Class J states. The competing effects of V-J' on the direct and exchange energies determine the relative stability of Class J states. We show that the spin-split and Rashba-like phases are the most favored ground states within Class J because they have the minimum anisotropy in `polarized spin'. On a square lattice we find that the spin-split phase is always favored for near-empty bands; above a critical filling, we predict a transition from the paramagnetic to the Rashba-like phase at Jc1 and a second transition to the spin-split state at Jc2>Jc1. An energetic comparison with ferromagnetism highlights the importance of the role of V in the stability of Class J states. We discuss the relevance of our results to (i) the α and β phases proposed by Wu and Zhang in the Fermi Liquid formalism and (ii) experimental observations of spin-orbit splitting in Au(111) surface states.