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Symmetry breaking and phase transitions in Bose-Einstein condensates with spin–orbital-angular-momentum coupling

Yuxiong Duan, Y. M. Bidasyuk, A. Surzhykov

2020Physical review. A/Physical review, A21 citationsDOIOpen Access PDF

Abstract

Theoretical study is presented for a spinor Bose-Einstein condensate, whose two components are coupled by copropagating Raman beams with different orbital angular momenta. The investigation is focused on the behavior of the ground state of this condensate, depending on the atom-light coupling strength. By analyzing the ground state, we have identified a number of quantum phases, which reflect the symmetries of the effective Hamiltonian and are characterized by the specific structure of the wave function. In addition to the well-known stripe, polarized, and zero-momentum phases, our results show that the system can support phases whose wave functions contain a complex vortex molecule. Such a molecule plays an important role in the continuous phase transitions of the system. The predicted behavior of vortex-molecule phases can be examined in cold-atom experiments using currently existing techniques.

Topics & Concepts

PhysicsBose–Einstein condensateAngular momentumAngular momentum couplingHamiltonian (control theory)Ground stateQuantum mechanicsSpinorTotal angular momentum quantum numberAzimuthal quantum numberWave functionOrbital angular momentum of lightVortexQuantum phase transitionCondensed matter physicsPhase transitionMathematical optimizationMathematicsThermodynamicsCold Atom Physics and Bose-Einstein CondensatesStrong Light-Matter InteractionsQuantum optics and atomic interactions