Finite-temperature dynamics of a bosonic Josephson junction

Bidasyuk, Y. M.; Weyrauch, M.; Momme, M. R.; Prikhodko, O. O.

doi:10.1088/1361-6455/aae022

Cited by 17 publications

(14 citation statements)

References 39 publications

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“…This is characterized by high-frequency coherent oscillations of the population imbalance around a non-zero value, driven by a monotonically increasing relative phase [10,13,[15][16][17][18]. Even without thermally induced decay of the population imbalance [12,17,21], the stability of MQST depends on whether vortices nucleated inside the barrier annihilate therein [22,23], or penetrate into the superfluid reservoirs. Re-cent experiments with inhomogeneous three-dimensional Fermi superfluids [24,25] revealed the intimate connection between phase slippage and dissipation arising from vortices created within the barrier and shed into the superfluid.…”

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confidence: 99%

“…We stress that the standard twomode model [10,13] that captures both Josephson and MQST dynamics of previous experiments [16,18] is out of its validity range due to the considered values of the ratio V 0 /µ and to the thinness of the junctions [38]. Although dissipative effects can be phenomenologically modeled by damped two-mode [21,35,36] and RSJ-circuital models [7], such approaches provide limited insight into the microscopic dissipative processes.…”

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confidence: 99%

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Critical Transport and Vortex Dynamics in a Thin Atomic Josephson Junction

et al. 2020

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We study the onset of dissipation in an atomic Josephson junction between Fermi superfluids in the molecular Bose-Einstein condensation limit of strong attraction. Our simulations identify the critical population imbalance and the maximum Josephson current delimiting dissipationless and dissipative transport, in quantitative agreement with recent experiments. We unambiguously link dissipation to vortex ring nucleation and dynamics, demonstrating that quantum phase slips are responsible for the observed resistive current. Our work directly connects microscopic features with macroscopic dissipative transport, providing a comprehensive description of vortex ring dynamics in three-dimensional inhomogeneous constricted superfluids at zero and finite temperatures. arXiv:1905.08893v2 [cond-mat.quant-gas]

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confidence: 99%

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Critical Transport and Vortex Dynamics in a Thin Atomic Josephson Junction

et al. 2020

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“…We conclude that this is the optimal cut-off energy for such system and use only this value for the rest of this section. It is worth noting that, in realistic finite-temperature calculations, the choice of the cut-off energy is a nontrivial problem, and its definition is related to the temperature of the sys- tem [10,11,19]. For the purposes of the present feasibility study, which does not address any real finitetemperature processes, the cut-off value is considered only as a measure of the basis size and, consequently, the quality of a spectral representation of the condensate wave function.…”

Section: Numerical Verificationmentioning

confidence: 99%

“…The latter will be the main focus of the present work. A wide range of physical problems addressed with PGPE and its modifications includes, in particular, the Bosecondensation and quasicondensation [6][7][8], dynamical generation [9] and decay [10] of quantum vortices, and dissipative bosonic Josephson effect [11].…”

Section: Introductionmentioning

confidence: 99%

Projected Gross–Pitaevskii Equation for Ring-Shaped Bose–Einstein Condensates

Prikhodko

Bidasyuk

2021

Ukr. J. Phys.

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We propose an alternative implementation of the projected Gross–Pitaevskki equation adapted for a numerical modeling of the atomic Bose–Einstein condensate trapped in a toroidally shaped potential. We present an accurate efficient scheme to evaluate the required matrix elements and to calculate tthe ime evolution of the matter wave field. We analyze the stability and accuracy of the developed method for equilibrium and nonequilibrium solutions in a ring-shaped trap with an additional barrier potential corresponding to recent experimental realizations.

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“…( 14) a term proportional to the RCSJ normal current −G∆µ, along with a phenomenological value of the conductance G [20]. More elaborate procedures that quantitatively take into account the effect of damping at a finite temperature could be carried out by resorting to a stochastic projected GP equation [42].…”

Section: Adiabatic Barrier Motion: Dc-ac Transition and Hysteretic Phenomenamentioning

confidence: 99%

dc to ac Josephson transition in a dc atom superconducting quantum interference device

Cataldo

2020

Phys. Rev. A

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We analyze the effect of the barrier motion on the Bose-Hubbard Hamiltonian of a ring-shaped Bose-Einstein condensate interrupted by a pair of Josephson junctions, a configuration which is the cold atom analog of the well-known dc superconducting quantum interference device (SQUID).Such an effect is also shown to modify the Heisenberg equation of motion of the boson field operator in the two-mode approximation, where a hysteretic contribution that could affect the dynamics for accelerated or overlapping barriers is identified. By studying the energy landscape as a function of order and control parameters, we determine the diagram with the location of the dc and ac Josephson regimes, along with the critical points that are shown to depend on the junctions position. We analyze the dc to ac Josephson transition for adiabatic barrier trajectories that lead to a final uniform velocity, or which perform symmetric velocity paths. We show that such symmetric trajectories may induce, when reaching the critical point, highly hysteretic oscillating return paths within the dc regime, similar to the underdamped hysteresis loops arising from the action of a resistive flow in the ac regime. We also consider nonequilibrium initial conditions resulting from a finite phase difference on either side of the junctions, along with the critical features of such a parameter. An excellent agreement between the Gross-Pitaevskii simulations and the two-mode results is found in all cases.

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Finite-temperature dynamics of a bosonic Josephson junction

Cited by 17 publications

References 39 publications

Critical Transport and Vortex Dynamics in a Thin Atomic Josephson Junction

Critical Transport and Vortex Dynamics in a Thin Atomic Josephson Junction

Projected Gross–Pitaevskii Equation for Ring-Shaped Bose–Einstein Condensates

dc to ac Josephson transition in a dc atom superconducting quantum interference device

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