Trapped fermions in a synthetic non-Abelian gauge field

TL;DR

This paper investigates how a non-Abelian gauge field affects the shape and size of trapped fermion clouds, revealing anisotropic deformations and potential for simulating condensed matter phenomena in cold atom systems.

Contribution

It develops an adiabatic approach including Berry phase effects to analyze fermion cloud deformation under non-Abelian gauge fields in traps, providing analytical and numerical insights.

Findings

Cloud size decreases with increasing gauge coupling 

Anisotropic cloud shapes emerge for certain gauge configurations

Observable anisotropy increases with 

Abstract

On increasing the coupling strength ($\lambda$) of a non-Abelian gauge field that induces a generalized Rashba spin-orbit interaction, the topology of the Fermi surface of a homogeneous gas of noninteracting fermions of density $\rho \sim \kf^3$ undergoes a change at a critical value, $\lambda_T \approx \kf$ [Phys. Rev. B {\bf 84}, 014512 (2011)]. In this paper we analyze how this phenomenon affects the size and shape of a cloud of spin-$\half$ fermions trapped in a harmonic potential such as those used in cold atom experiments. We develop an adiabatic formulation, including the concomitant Pancharatnam-Berry phase effects, for the one particle states in the presence of a trapping potential and the gauge field, obtaining approximate analytical formulae for the energy levels for some high symmetry gauge field configurations of interest. An analysis based on the local density approximation reveals that, for a given number of particles, the cloud shrinks in a {\em characteristic fashion with increasing $\lambda$}. For an isotropic harmonic trap, the local density approximation predicts a spherical cloud for all gauge field configurations, which are anisotropic in general. We show, via a calculation of the cloud shape using exact eigenstates, that for certain gauge field configurations there is systematic and observable anisotropy in the cloud shape that increases with increasing gauge coupling $\lambda$. These results should be useful in the design of cold atom experiments with fermions in non-Abelian gauge fields. An important spin-off of our adiabatic formulation is that it reveals exciting possibilities for the cold-atom realization of interesting condensed matter Hamiltonians (eg. quantum hall spherical geometry) by using a non-Abelian gauge field in conjunction with another potential.