Dynamical Transitions in Trapped Superfluids Excited by Alternating Fields
Abstract
The paper presents a survey of some dynamical transitions in nonequilibrium trapped Bose-condensed systems subject to the action of alternating fields. Nonequilibrium states of trapped systems can be realized in two ways, resonant and nonresonant. Under resonant excitation, several coherent modes are generated by external alternating fields, whose frequencies are tuned to resonance with some transition frequencies of the trapped system. A Bose system of trapped atoms with Bose-Einstein condensate can display two types of the Josephson effect, the standard one, when the system is separated into two or more parts in different locations or when there are no any separation barriers, but the system becomes nonuniform due to the coexistence of several coherent modes interacting with each other, which is termed internal Josephson effect. The mathematics in both these cases is similar. We concentrate on the internal Josephson effect. Systems with nonlinear coherent modes demonstrate rich dynamics, including Rabi oscillations, Josephson effect, and chaotic motion. Under Josephson effect, there exist dynamic transitions that are similar to phase transitions in equilibrium systems. The bosonic Josephson effect is shown to be realizable not only for weakly interacting systems, but also in superfluids, with not necessarily weak interactions. Sufficiently strong nonresonant excitation can generate several types of nonequilibrium states comprising vortex germs, vortex rings, vortex lines, vortex turbulence, droplet turbulence, and wave turbulence. Nonequilibrium states can be characterized and distinguished by effective temperature, effective Fresnel number, and dynamic scaling laws.