The resource theory of informational nonequilibrium in thermodynamics

Gour, Gilad; Müller, Markus P.; Narasimhachar, Varun; Spekkens, Robert W.; Halpern, Nicole Yunger

doi:10.1016/j.physrep.2015.04.003

Cited by 398 publications

(578 citation statements)

References 67 publications

(103 reference statements)

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“…As an example, the statement of the second law of thermodynamics in the presence of an ancilla [1,2] or, when the system has coherence [3,4], has been established in great details, from where the classical version of the second law emerges under appropriate limits. The study of thermodynamics in quantum domain can be approached from different directions such as information-theoretic point of view [5][6][7][8][9][10] or resource-theoretic aspect [11][12][13]. Another important constituent, in this area of study, is the work extraction from quantum systems [14][15][16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Implications of Coupling in Quantum Thermodynamic Machines

Thomas

Banik

Ghosh

2017

Entropy

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Abstract:We study coupled quantum systems as the working media of thermodynamic machines. Under a suitable phase-space transformation, the coupled systems can be expressed as a composition of independent subsystems. We find that for the coupled systems, the figures of merit, that is the efficiency for engine and the coefficient of performance for refrigerator, are bounded (both from above and from below) by the corresponding figures of merit of the independent subsystems. We also show that the optimum work extractable from a coupled system is upper bounded by the optimum work obtained from the uncoupled system, thereby showing that the quantum correlations do not help in optimal work extraction. Further, we study two explicit examples; coupled spin-1/2 systems and coupled quantum oscillators with analogous interactions. Interestingly, for particular kind of interactions, the efficiency of the coupled oscillators outperforms that of the coupled spin-1/2 systems when they work as heat engines. However, for the same interaction, the coefficient of performance behaves in a reverse manner, while the systems work as the refrigerator. Thus, the same coupling can cause opposite effects in the figures of merit of heat engine and refrigerator.

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Section: Introductionmentioning

confidence: 99%

Implications of Coupling in Quantum Thermodynamic Machines

Thomas

Banik

Ghosh

2017

Entropy

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“…Analogously to thermodynamic resource theory [23][24][25], the regime of validity can be formulated in terms of allowed operations. Instead of giving a validity condition it is possible to restrict the set of allowed physical processes.…”

Section: Allowed Operationsmentioning

confidence: 99%

Additional energy-information relations in thermodynamics of small systems

Uzdin

2017

Phys. Rev. E

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The Clausius inequality (CI) form of the second law of thermodynamics relates information changes (entropy) to changes in the first moment of the energy (heat and indirectly also work). Are there similar relations between other moments of the energy distribution, and other information measures, or is the Clausius inequality a one of a kind instance of the energy-information paradigm? If there are additional relations, can they be used to make predictions on measurable quantities? Changes in the energy distribution beyond the first moment (average heat or work) are especially important in small systems which are often very far from thermal equilibrium. The generalized Clausius inequalities (GCI's), here derived, provide positive answers to the two questions above and add another layer to the fundamental connection between energy and information. To illustrate the utility of the new GCI's, we find scenarios where the GCI's yield tighter constraints on performance (e.g. in thermal machines) compared to the second law. To obtain the GCI's we use the Bregman divergence -a mathematical tool found to be highly suitable for energy-information studies. The quantum version of the GCI's provides a thermodynamic meaning to various quantum coherence measures. It is intriguing to fully map the regime of validity of the GCI's and extend the present results to more general scenarios including continuous systems and particles exchange with the baths.

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“…Yet heat, work, and entropy characterize the few-particle scales that experimentalists can increasingly control (e.g., [23][24][25][26][27]), as well as single trials. Small scales have been described by TRTs (e.g., [2,[28][29][30][31][32][33]). These results fall under the umbrella of one-shot statistical mechanics, an application of the one-shot information theory that generalizes Shannon theory [34].…”

Section: One-shot Statistical Mechanicsmentioning

confidence: 99%

“…depends on the greatest probability p max in a distribution P or on the greatest eigenvalue p max of a quantum state ρ. H ∞ relates to the work that a TRT agent must invest to create a state (ρ, H) [2,29]. The work extractable from (ρ, H) relates to…”

Section: One-shot Statistical Mechanicsmentioning

confidence: 99%

Toward Physical Realizations of Thermodynamic Resource Theories

Halpern

2016

Information and Interaction

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Conventional statistical mechanics describes large systems and averages over many particles or over many trials. But work, heat, and entropy impact the small scales that experimentalists can increasingly control, e.g., in single-molecule experiments. The statistical mechanics of small scales has been quantified with two toolkits developed in quantum information theory: resource theories and one-shot information theory. The field has boomed recently, but the theorems amassed have hardly impacted experiments. Can thermodynamic resource theories be realized experimentally? Via what steps can we shift the theory toward physical realizations? Should we care? I present eleven opportunities in physically realizing thermodynamic resource theories.

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The resource theory of informational nonequilibrium in thermodynamics

Cited by 398 publications

References 67 publications

Implications of Coupling in Quantum Thermodynamic Machines

Implications of Coupling in Quantum Thermodynamic Machines

Additional energy-information relations in thermodynamics of small systems

Toward Physical Realizations of Thermodynamic Resource Theories

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