Abstract
We study the static and the dynamic response of coherently coupled two component Bose–Einstein condensates due to a spin-dipole perturbation. The static dipole susceptibility is determined and is shown to be a key quantity to identify the second order ferromagnetic transition occurring at large inter-species interaction. The dynamics, which is obtained by quenching the spin-dipole perturbation, is very much affected by the system being paramagnetic or ferromagnetic and by the correlation between the motional and the internal degrees of freedom. In the paramagnetic phase the gas exhibits well defined out-of-phase dipole oscillations, whose frequency can be related to the susceptibility of the system using a sum rule approach. In particular in the interaction SU(2) symmetric case, i.e., all the two-body interactions are the same, the external dipole oscillation coincides with the internal Rabi flipping frequency. In the ferromagnetic case, where linear response theory in not applicable, the system shows highly non-linear dynamics. In particular we observe phenomena related to ground state selection: the gas, initially trapped in a domain wall configuration, reaches a final state corresponding to the magnetic ground state plus small density ripples. Interestingly, the time during which the gas is unable to escape from its initial configuration is found to be proportional to the square root of the wall surface tension.
Highlights
Ultra-cold gases allow the realisations of multicomponent Bose-Einstein condensates (BECs)
In the following we show that the static and the dynamic response to an out-of-phase dipole perturbation is very rich and captures many relevant phenomena related to the paramagnetic-ferromagnetic-like phase transition of the system
In the present work we analyse in details the static and dynamic response of a trapped coherently driven 2component condensate to spin-dipole probe
Summary
We consider an atomic Bose gas at zero temperature, where each atom of mass m has two internal levels |a and |b. The condensed phase for a two-component Bose gas is described by a complex spinor order parameter (ψa(r, t), ψb(r, t)), where ψi, i ∈ {a, b} is the wave function macroscopically occupied by atoms in the internal state |i. The latter is normalised to the total number of atoms Ni in the state |i. If the condition Eq (4) is not satisfied at the center of the trap, where the total density is maximum, the whole system is unpolarised This allows us to introduce a critical value of Rabi coupling defined by. An example of the structure for an equal number of atoms in both hyperfine levels is shown in Fig. 2 (a1)
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