Making statistics work: a quantum engine in the BEC-BCS crossover

Koch, Jennifer; Menon, Keerthy; Cuestas, Eduardo; Barbosa, Sian; Lutz, Eric; Fogarty, Thomás; Busch, Thomas; Widera, Artur

doi:10.48550/arxiv.2209.14202

Cited by 4 publications

(4 citation statements)

References 40 publications

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“…On the experimental side, a recently reported realization of an isothermal engine with ultra-cold atoms and tunable interactions that change the quantum statistics of the working system, provides an exciting subject for future studies [60]. Here, it is a priori unclear how a geometric framework should be constructed, since, at least in an effectively non-interacting model, the statistics of quantum particles cannot be continuously tuned between Bose-Einstein and Fermi-Dirac.…”

Section: Concluding Perspectivesmentioning

confidence: 99%

“…A promising avenue towards scaling up the power and constancy of quantum thermal machines is to replace working systems with few degrees of freedom by many-body systems capable of hosting collective effects, which may lead to uncovering new mechanisms of energy conversion . Such effects, whose thermodynamics is yet to be fully understood, include: tunable interactions between particles, which can be used for work-extraction [44][45][46]; super-radiance and broken time-translation symmetry, which emerge in multi-level systems coupled to a thermal bath via collective observables [47][48][49][50][51][52]; quantum phase transitions [53][54][55][56] or quantum statistics, which provides a means of controlling an effective pressure that has no classical counterpart [57][58][59][60][61]. Thermodynamic geometry offers a powerful tool to analyse these phenomena from a unifying perspective and thus a potential avenue towards a universal framework describing how many-body effects can alter the performance of quantum thermal machines.…”

Section: Introductionmentioning

confidence: 99%

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Thermodynamic geometry of ideal quantum gases: a general framework and a geometric picture of BEC-enhanced heat engines

et al. 2023

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Thermodynamic geometry provides a physically transparent framework to describe thermodynamic processes in meso- and micro-scale systems that are driven by slow variations of external control parameters. Focusing on periodic driving for thermal machines, we extend this framework to ideal quantum gases. To this end, we show that the standard approach of equilibrium physics, where a grand-canonical ensemble is used to model a canonical one by fixing the mean particle number through the chemical potential, can be extended to the slow driving regime in a thermodynamically consistent way. As a key application of our theory, we use a Lindblad-type quantum master equation to work out a dynamical model of a quantum many-body engine using a harmonically trapped Bose-gas. Our results provide a geometric picture of the BEC-induced power enhancement that was previously predicted for this type of engine on the basis of an endoreversible model [New J. Phys. 24, 025001 (2022)]. Using an earlier derived universal trade-off relation between power and efficiency as a benchmark, we further show that the Bose-gas engine can deliver significantly more power at given efficiency than an equally large collection of single-body engines. Our work paves the way for a more general thermodynamic framework that makes it possible to systematically assess the impact of quantum many-body effects on the performance of thermal machines.

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Section: Concluding Perspectivesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Thermodynamic geometry of ideal quantum gases: a general framework and a geometric picture of BEC-enhanced heat engines

et al. 2023

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“…While recent years have seen the experimental implementation of some quantum thermodynamic cycles [ 11 , 13 , 31 , 32 ], these devices serve primarily as proof-of-concept prototypes rather than a practical means of extracting useful energy in the form of work. This is since coupling a quantum thermal machine to another device to extract and use the work is a complex and challenging task within the frameworks in which these quantum engines have been implemented.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Efficiency at Maximum Power in a Fock–Darwin Model Quantum Dot Engine

Peña

Myers

Órdenes

et al. 2023

Entropy

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We study the performance of an endoreversible magnetic Otto cycle with a working substance composed of a single quantum dot described using the well-known Fock–Darwin model. We find that tuning the intensity of the parabolic trap (geometrical confinement) impacts the proposed cycle’s performance, quantified by the power, work, efficiency, and parameter region where the cycle operates as an engine. We demonstrate that a parameter region exists where the efficiency at maximum output power exceeds the Curzon–Ahlborn efficiency, the efficiency at maximum power achieved by a classical working substance.

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“…A promising approach to the first challenge is to replace working media with few degrees of freedom, such as single spins, with many-body systems, where collective effects can arise from the co-action of large numbers of constituents [13]. Recent theoretical and experimental studies have shown that the power of thermal devices can be significantly enhanced by exploiting, for example, many-body coherence in non-interacting systems, which can give rise to super-radiance and related phenomena [14][15][16][17][18][19][20][21][22][23][24], or interactions and quantum many-body statistics in ultra-cold atomic systems [25][26][27][28][29][30][31][32][33][34][35]. Strongly interacting Rydberg atoms and ions provide another, yet relatively unexplored, platform to implement quantum thermal machines with many degrees of freedom [39].…”

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confidence: 99%