Coherently Coupled Mixtures of Ultracold Atomic Gases

This article summarizes some of the relevant features exhibited by binary mixtures of Bose-Einstein condensates in the presence of coherent coupling at zero temperature. The coupling, which is experimentally produced by proper photon transitions, can involve either negligible momentum transfer from the electromagnetic radiation (Rabi coupling) or large momentum transfer (Raman coupling) associated with spin-orbit effects. The nature of the quantum phases exhibited by coherently coupled mixtures is discussed in detail, including their paramagnetic, ferromagnetic, and, in the case of spin-orbit coupling, supersolid phases. The behavior of the corresponding elementary excitations is discussed, with explicit emphasis on the novel features caused by the spin-like degree of freedom. Focus is further given to the topological excitations (solitons, vortices) as well as to the superfluid properties. This review also points out relevant open questions that deserve more systematic theoretical and experimental investigations.

Automated summary

This article summarizes the relevant features of binary mixtures of Bose-Einstein condensates in the presence of coherent coupling at zero temperature. The nature of the quantum phases, such as paramagnetic, ferromagnetic, and supersolid phases, are discussed in detail. The behavior of elementary excitations and the novel features caused by the spin-like degree of freedom are also discussed. The article further focuses on topological excitations (solitons, vortices) and superfluid properties, and highlights open questions for further theoretical and experimental investigations.