Dynamics of hot Bose-Einstein condensates: stochastic Ehrenfest relations for number and energy damping

McDonald, R. G.; Barnett, Peter S.; Atayee, Fradom; Bradley, Ashton S.

doi:10.21468/scipostphys.8.2.029

Cited by 5 publications

(3 citation statements)

References 46 publications

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“…The dynamical noise term η, subject to noise correlations given by η * (r, t)η(r , t ) = 2 γk B T δ(t − t )δ(r − r ), means that each simulation run is unique. Finally, P is a projector which constrains the dynamics of the system up to an energy cutoff cut (µ) = 2µ-consistent with previous treatments [51,52]-for input chemical potential µ.…”

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confidence: 99%

Two-Dimensional Supersolid Formation in Dipolar Condensates

Bland,

Poli,

Politi

et al. 2021

Preprint

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Dipolar condensates have recently been coaxed into supersolid phases supporting both superfluid and crystal excitations. While one-dimensional (1D) supersolids may be prepared via a roton instability, we find that such a procedure in two dimensions (2D) leads to greater heating. We go on to show that 2D roton modes have little in common with the supersolid configuration: instead, unstable centralized rotons trigger a process of nonlinear crystal growth. By evaporatively cooling directly into the supersolid phase-hence bypassing the first-order roton instability-we experimentally produce a 2D supersolid in a near-circular trap. We develop a stochastic Gross-Pitaevskii theory that includes beyond-meanfield effects to further explore the formation process. We calculate the static structure factor for a 2D supersolid, and compare to a 1D array. These results provide insight into the process of supersolid formation in 2D, and define a realistic path to the formation of large two-dimensional supersolid arrays.

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confidence: 99%

Two-Dimensional Supersolid Formation in Dipolar Condensates

Bland,

Poli,

Politi

et al. 2021

Preprint

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“…It is straightforward to show that the drag potential causes energy dissipation of the condensate, since it is proportional to the negative of the divergence of the condensate current. Since damping is a weak correction to Hamiltonian dynamics, at leading order ∇ • j = −∂ t |ψ| 2 , and the potential damps density dynamics associated with sound, solitons, or moving vortex cores [19,33]. Note that a similar expression for the total current J(r ) is obtained for a rotating condensate [10].…”

Section: Theorymentioning

confidence: 99%

Steady-state theory of electron drag on polariton condensates

Mukherjee¹,

Bradley²,

Snoke³

2022

Preprint

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We present a general theory of drag on a condensate due to interactions with a moving thermal bath of non-condensate particles, adapted from previous theory of equilibration of a condensate in a trap. This theory can be used to model the polariton drag effect observed previously, in which an electric current passing through a polariton condensate gives a measurable momentum transfer to the condensate, and an effective potential energy shift.Polaritons inherently have a finite lifetime ∼ 20 − 200 ps inside a microcavity. It has been shown [22] that in the upper range of these lifetimes, polaritons can reach thermal equilibrium. In general, it is possible to observe the time evolution of a polariton condensate far from equilibrium all the way

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“…Generally it can be expected that energy damping will be important for density fluctuations in systems near particle equilibrium; such scenarios are common in ultracold Bose gases, e.g. sound waves, solitons, and other compressible excitations [70,71]. It is possible that the qualitative effect of energy damping on such excitations will be distinct from number damping, which may have important im-plications for the study of weak-wave turbulence in quantum fluids [72,73].…”

Section: Low-energy Modesmentioning

confidence: 99%

Mutual friction and diffusion of two-dimensional quantum vortices

Mehdi¹,

Hope²,

Szigeti³

et al. 2022

Preprint

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We present a microscopic theory of thermally-damped vortex motion in oblate atomic superfluids that accounts for previously neglected number-conserving interactions between superfluid and thermal atoms. This mechanism causes dissipation of vortex energy due to mutual friction, as well as Brownian motion of vortices due to thermal fluctuations. We present an analytic expression for the dimensionless mutual friction coefficient that gives excellent quantitative agreement with experimentally measured values, without any fitted parameters. Our work provides a microscopic origin for the damping and Brownian motion of quantized vortices in two-dimensional atomic superfluids, which has previously been limited to phenomenology.

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Dynamics of hot Bose-Einstein condensates: stochastic Ehrenfest relations for number and energy damping

Cited by 5 publications

References 46 publications

Two-Dimensional Supersolid Formation in Dipolar Condensates

Two-Dimensional Supersolid Formation in Dipolar Condensates

Steady-state theory of electron drag on polariton condensates

Mutual friction and diffusion of two-dimensional quantum vortices

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