Theory of Bosons in two-leg ladders with large magnetic fields

TL;DR

This paper analyzes the ground states of a Bose gas on a two-leg ladder under large magnetic fields, revealing three distinct phases with unique symmetry properties and excitation spectra, relevant for cold atom experiments.

Contribution

It introduces a mean-field phase diagram for bosons in a two-leg ladder with large magnetic fields, identifying three novel phases and their symmetry-breaking characteristics.

Findings

Identified three phases: SCCP, BLP, MDP.

Found a roton-maxon excitation spectrum in the BLP.

Predicted instability of BLP as roton energy softens.

Abstract

We calculate the ground state of a Bose gas trapped on a two-leg ladder where Raman-induced hopping mimics the effect of a large magnetic field. In the mean-field limit, where there are large numbers of particles per site, this maps onto a uniformly frustrated two-leg ladder classical spin model. The net particle current always vanishes in the ground state, but generically there is a finite "chiral current", corresponding to equal and opposite flow on the two legs. We vary the strength of the hopping across the rungs of the ladder and the interaction between the bosons. We find three phases: (1) A "saturated chiral current phase" (SCCP), where the density is uniform and the chiral current is simply related to the strength of the magnetic field. In this state the only broken symmetry is the $U(1)$ condensate phase. (2) A "biased ladder phase" (BLP), where the density is higher on one leg than the other. The fluid velocity is higher on the lower density leg, so the net current is zero. In addition to the $U(1)$ condensate phase, this has a broken $Z_2$ reflection symmetry. (3) A "modulated density phase" (MDP), where the atomic density is modulated along the ladder. In addition to the $U(1)$ condensate phase, this has a second broken $U(1)$ symmetry corresponding to translations of the density wave. We further study the fluctuations of the condensate in the BLP, finding a roton-maxon like excitation spectrum. Decreasing the hopping along the rungs softens the spectrum. As the energy of the "roton" reaches to zero, the BLP becomes unstable. We describe the experimental signatures of these phases, including the response to changing the frequency of the Raman transition.