Spontaneous population imbalance in two-component Bose and Fermi gases

TL;DR

This paper investigates how strong intercomponent repulsion in one-dimensional two-component Bose and Fermi gases causes spontaneous population imbalance, revealing phase transitions influenced by intercomponent hopping and emergent symmetries.

Contribution

It demonstrates the emergence of spontaneous population imbalance and ferromagnetism in 1D two-component gases, analyzing the effects of intercomponent hopping on phase transitions and symmetry.

Findings

Strong intercomponent repulsion induces population imbalance.

Transition type depends on intercomponent hopping: first order without hopping, Ising with hopping.

Phase diagram and symmetry properties are accurately characterized.

Abstract

We study two-component (or pseudo-spin-1/2) Bose or Fermi gases in one dimension, in which particles are convertible between the components. Through bosonization and numerical analyses of a simple lattice model, we demonstrate that, in such gases, a strong intercomponent repulsion induces spontaneous population imbalance between the components, namely, the ferromagnetism of the pseudo spins. The imbalanced phase contains gapless charge excitations characterized as a Tomonaga-Luttinger liquid and gapped spin excitations. We uncover a crucial effect of the intercomponent particle hopping on the transition to the imbalanced phase. In the absence of this hopping, the transition is of first order. At the transition point, the energy spectrum reveals certain degeneracy indicative of an emergent SU(2) symmetry. With an infinitesimal intercomponent hopping, the transition becomes of Ising type. We determine the phase diagram of the model accurately and test the reliability of the weak-coupling bosonization formalism.