Electron-phonon interaction in a spin-orbit coupled quantum wire with a gap

Abstract

Interaction between electron and acoustic phonon in an in-plane magnetic field induced gapped quantum wire with Rashba spin-orbit interaction is studied. We calculate acoustic phonon limited resistivity () and phonon-drag thermopower (Sg) due to two well known mechanisms of electron-phonon interaction namely, deformation potential (DP) and piezoelectric (PE) scattering. In the so called Bloch-Gruneisen temperature limit both and Sg depend on temperature (T) in a power law fashion i.e. or Sg TT. For resistivity, T takes the value 5 and 3 due to DP and PE scattering respectively. On the other hand, T is 4 and 2 due to DP and PE scattering, respectively for phonon-drag thermopower. Additionally, we find numerically that T depends on Rashba parameter (α) and electron density (n). The dependence of T on α becomes more prominent at lower density. We also study the variations of and Sg with carrier density in the Bloch-Gruneisen regime. Through a numerical analysis a similar power law dependence or Sg n-n is established in which the effective exponent n undergoes a smooth transition from a low density behavior to a high density behavior. At a higher density regime, n matches excellently with the value obtained from theoretical arguments. Approximate analytical expressions for both resistivity and phonon-drag thermopower in the Bloch-Gruneisen regime are given.