English

Competing interactions in population-imbalanced two-component Bose-Einstein condensates

Quantum Gases 2016-08-22 v1

Abstract

We consider a two-component Bose-Einstein condensate with and without synthetic "spin-orbit" interactions in two dimensions. Density- and phase-fluctuations of the condensate are included, allowing us to study the impact of thermal fluctuations and density-density interactions on the physics originating with spin-orbit interactions. In the absence of spin-orbit interactions, we find that inter-component density interactions deplete the minority condensate. The thermally driven phase transition is driven by coupled density and phase-fluctuations, but is nevertheless shown to be a phase-transition in the Kosterlitz-Thouless universality class with close to universal amplitude ratios irrespective of whether both the minority- and majority condensates exist in the ground state, or only one condensate exists. In the presence of spin-orbit interactions we observe three separate phases, depending on the strength of the spin-orbit coupling and inter-component density-density interactions: a phase-modulated phase with uniform amplitudes for small intercomponent interactions, a completely imbalanced, effectively single-component, condensate for intermediate spin-orbit coupling strength and suficciently large inter-component interactions, and a phase-modulated \textit{and} amplitude-modulated phase for sufficiently large values of both the spin-orbit coupling and the inter-component density-density interactions. The phase which is modulated by a single \bvq\bv q-vector only is observed to transition into an isoptropic liquid through a strong de-pinning transition with periodic boundary conditions, which weakens with open boundaries.

Keywords

Cite

@article{arxiv.1608.03300,
  title  = {Competing interactions in population-imbalanced two-component Bose-Einstein condensates},
  author = {Peder N. Galteland and Asle Sudbø},
  journal= {arXiv preprint arXiv:1608.03300},
  year   = {2016}
}

Comments

15 pages, 14 figures. Accepted for publication in Physical Review B

R2 v1 2026-06-22T15:17:12.753Z