Entropy Production in Open Systems: The Predominant Role of Intraenvironment Correlations

Ptaszyński, Krzysztof; Esposito, Massimiliano

doi:10.1103/physrevlett.123.200603

Cited by 84 publications

(86 citation statements)

References 34 publications

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“…An entropic formulation of the second law can be derived in terms of the non-negativity of the entropy production (see, for example, Refs. [61][62][63] and Chapter 28 by R. Uzdin in Ref. [1]):…”

Section: A Partial Scenariomentioning

confidence: 99%

Quantum machines powered by correlated baths

Chiara

Antezza

2020

Phys. Rev. Research

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We consider thermal machines powered by locally equilibrium reservoirs that share classical or quantum correlations. The reservoirs are modeled by the so-called collisional model or repeated interactions model. In our framework, two reservoir particles, initially prepared in a thermal state, are correlated through a unitary transformation and afterward interact locally with the two quantum subsystems which form the working fluid. For a particular class of unitaries, we show how the transformation applied to the reservoir particles affects the amount of heat transferred and the work produced. We then compute the distribution of heat and work when the unitary is chosen randomly, proving that the total swap transformation is the optimal one. Finally, we analyze the performance of the machines in terms of classical and quantum correlations established among the microscopic constituents of the machine.

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Section: A Partial Scenariomentioning

confidence: 99%

Quantum machines powered by correlated baths

Chiara

Antezza

2020

Phys. Rev. Research

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“…Telescopic relative entropy.-Relative entropy is a fundamental quantity in statistical mechanics and information theory, both at the classical and quantum level [51][52][53]. It can be interpreted as a quantifier of the error rate in discriminating two probability distributions in the limit of many measurement repetitions and it also plays a distinguished role in quantum thermodynamics and its foundations, especially in analyzing the formulation of the second law of thermodynamics in the quantum regime [54][55][56][57]. The expression of the QRE first introduced by Umegaki [58] reads Sðϱ; σÞ ¼ Trðϱ log ϱ − ϱ log σÞ.…”

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confidence: 99%

Entropic Bounds on Information Backflow

2021

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“…not subject to equations of motion; alternative justifications rooted in the sheer size of the number of bath coordinates were also given). [In a more elaborate treatment inclusive of bath dynamics the foregoing manipulation of ( ) 2 H δ would have been done in reverse: by tracing over the N-variables (the total system minus the bath) and obtaining an "Effective Hamiltonian" representing interaction within the bath coordinates, inducing correlations and entropy increase, for which predictions have already been made in [34] [35]. By their estimate, this occurs mainly well after the SR process, thus allowing one to treat the process of SR itself at the level here adopted.…”

Section: Controlmentioning

confidence: 99%

A Quantum State Scenario for Biological Self-Replication

Englman¹

2021

OJBIPHY

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With the prevalent conception of self-replication (SR, a hallmark of living systems) as a non-equilibrium process subject to thermodynamic laws, a complementary approach derives the low energy quantum states arising from a Hamiltonian that appears to be specific for bio-systems by its containing some strongly binding terms. The bindings attract properties of the template (T) and the reactants to form a replicate (R). The criterion for SR that emerges from the theory is that second order (bi-linear) interaction terms between degrees of motion of T-R and the thermal bath dominate negatively over a linear self-energy term, and thereby provide a binding between the attributes of T and R. The formalism (reminiscent of the Kramers-Anderson mechanism for superexchange) is from first principles, but hinges on a drastic simplification by modelling the T, R and bath variables on interacting qubits and by congesting the attraction into a single (control) parameter. The development relies on further simplifying features, such as Random Phase Approximations and an Effective Hamiltonian formalism. The entropic balance to replication is considered and found to reside in the far surroundings.

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Entropy Production in Open Systems: The Predominant Role of Intraenvironment Correlations

Cited by 84 publications

References 34 publications

Quantum machines powered by correlated baths

Quantum machines powered by correlated baths

Entropic Bounds on Information Backflow

A Quantum State Scenario for Biological Self-Replication

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