Orbital ferromagnetism in interacting few-electron dots with strong spin-orbit coupling

Abstract

We study the ground state of N weakly interacting electrons (with N 10) in a two-dimensional parabolic quantum dot with strong Rashba spin-orbit coupling. Using dimensionless parameters for the Coulomb interaction, λ 1, and the Rashba coupling, α 1, the low-energy physics is characterized by an almost flat single-particle dispersion. From an analytical approach for α ∞ and N=2, and from numerical exact diagonalization and Hartree-Fock calculations, we find a transition from a conventional unmagnetized ground state (for λ<λc) to an orbital ferromagnet (for λ>λc), with a large magnetization and a circulating charge current. We show that the critical interaction strength, λc=λc(α,N), vanishes in the limit α ∞.