Non-Abelian Aharonov-Casher Phase Factor in Mesoscopic Systems

Abstract

The matrix-valued Aharonov-Casher phase factor FAC (related to the c-number Aharonov-Casher phase λAC) plays an important role in the physics of mesoscopic systems in which spin-orbit coupling is relevant. Yet, its relation to experimental observables is rather elusive. Based on the SU(2)-gauge-invariant formulation of the Schroedinger equation, we relate FAC to measurable quantities in electronic interferometers subject to electric fields that generate Rashba or Dresselhaus spin-orbit coupling. Specifically, we consider electron transmission through (i) a single-channel ring interferometer and (ii) a two-channel square interferometer. In both examples, we derive the closed expressions of the conductance and show them to be simple rational functions of the traceful part of FAC. In the second case, we also derive a closed expression for the electron spin polarization vector and find it to be a simple function of both the traceful and traceless parts of FAC. This analysis then suggests a direct way for an experimental access to this elusive quantity.