Ferromagnetic order of nuclear spins coupled to conduction electrons: a combined effect of the electron-electron and spin-orbit interactions

Abstract

We analyze the ordered state of nuclear spins embedded in an interacting two-dimensional electron gas (2DEG) with Rashba spin-orbit interaction (SOI). Stability of the ferromagnetic nuclear-spin phase is governed by nonanalytic dependences of the electron spin susceptibility ij on the momentum (q) and on the SOI coupling constant (α). The uniform (=0) spin susceptibility is anisotropic (with the out-of-plane component, zz, being larger than the in-plane one, xx, by a term proportional to U2(2kF)|α|, where U(q) is the electron-electron interaction). For ≤ 2m*|α|, corrections to the leading, U2(2kF)|α|, term scale linearly with for xx and are absent for zz. This anisotropy has important consequences for the ferromagnetic nuclear-spin phase: (i) the ordered state--if achieved--is of an Ising type and (ii) the spin-wave dispersion is gapped at =0. To second order in U(q), the dispersion a decreasing function of , and anisotropy is not sufficient to stabilize long-range order. However, renormalization in the Cooper channel for 2m*|α| is capable of reversing the sign of the -dependence of xx and thus stabilizing the ordered state. We also show that a combination of the electron-electron and SO interactions leads to a new effect: long-wavelength Friedel oscillations in the spin (but not charge) electron density induced by local magnetic moments. The period of these oscillations is given by the SO length π/m*|α|.