Abstract
We consider a time-dependent extension of a perturbative mean-field approach to the homogeneous dirty boson problem by considering how switching on and off a weak disorder potential affects the stationary state of an initially {equilibrated} Bose-Einstein condensate by the emergence of a disorder-induced condensate deformation. We find that in the switch on scenario the stationary condensate deformation turns out to be a sum of an equilibrium part{, that actually corresponds to adiabatic switching on the disorder,} and a dynamically-induced part, where the latter depends on the particular driving protocol. If the disorder is switched off afterwards, the resulting condensate deformation acquires an additional dynamically-induced part in the long-time limit, while the equilibrium part vanishes. {We also present an appropriate generalization to inhomogeneous trapped condensates.} Our results demonstrate that the condensate deformation represents an indicator of the generically non-equilibrium nature of steady states of a Bose gas in a temporally controlled weak disorder.
Highlights
All realistic physical systems inevitably involve a certain level of disorder due to the generic presence of an environment or a random distribution of imperfections
Building on an equilibrium inhomogeneous Bogoliubov theory [34], the results presented in [35] clarified the relation between the condensate depletion and condensate deformation in the presence of a weak, possibly random, external potential
Our results clearly demonstrate that the condensate deformation is an indicator of the nonequilibrium feature of steady states of a Bose gas in a temporally controlled weak disorder
Summary
All realistic physical systems inevitably involve a certain level of disorder due to the generic presence of an environment or a random distribution of imperfections. One has a potential of utilizing the disorder in order to engineer new states of matter, where the many-body localized phase is a recent prominent example [4, 5], which is currently being debated [6] This is in line with an ongoing quest to exploit the system environment as a tunable knob for quantum control [7,8,9,10,11,12,13]. Building on an equilibrium inhomogeneous Bogoliubov theory [34], the results presented in [35] clarified the relation between the condensate depletion and condensate deformation in the presence of a weak, possibly random, external potential We adopt such a notion of the condensate deformation here, use it as a measure of the average effect of the disorder and generalize it to the non-equilibrium context.
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