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Conditional work statistics of quantum measurements

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Conditional work statistics of quantum measurements. / Mohammady, Mohammad; Romito, Alessandro.
In: Quantum, Vol. 3, 19.08.2019, p. 175-191.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Mohammady, M & Romito, A 2019, 'Conditional work statistics of quantum measurements', Quantum, vol. 3, pp. 175-191. https://doi.org/10.22331/q-2019-08-19-175

APA

Mohammady, M., & Romito, A. (2019). Conditional work statistics of quantum measurements. Quantum, 3, 175-191. https://doi.org/10.22331/q-2019-08-19-175

Vancouver

Mohammady M, Romito A. Conditional work statistics of quantum measurements. Quantum. 2019 Aug 19;3:175-191. doi: 10.22331/q-2019-08-19-175

Author

Mohammady, Mohammad ; Romito, Alessandro. / Conditional work statistics of quantum measurements. In: Quantum. 2019 ; Vol. 3. pp. 175-191.

Bibtex

@article{739db3c407624c5793502b32019fc39c,
title = "Conditional work statistics of quantum measurements",
abstract = "In this paper we introduce a definition for conditional energy changes due to general quantum measurements, as the change in the conditional energy evaluated before, and after, the measurement process. By imposing minimal physical requirements on these conditional energies, we show that the most general expression for the conditional energy after the measurement is simply the expected value of the Hamiltonian given the post-measurement state. Conversely, the conditional energy before the measurement process is shown to be given by the real component of the weak value of the Hamiltonian. Our definition generalises well-known notions of distributions of internal energy change, such as that given by stochastic thermodynamics. By determining the conditional energy change of both system and measurement apparatus, we obtain the full conditional work statistics of quantum measurements, and show that this vanishes for all measurement outcomes if the measurement process conserves the total energy. Additionally, by incorporating the measurement process within a cyclic heat engine, we quantify the non-recoverable work due to measurements. This is shown to always be non-negative, thus satisfying the second law, and will be independent of the apparatus specifics for two classes of projective measurements.",
author = "Mohammad Mohammady and Alessandro Romito",
year = "2019",
month = aug,
day = "19",
doi = "10.22331/q-2019-08-19-175",
language = "English",
volume = "3",
pages = "175--191",
journal = "Quantum",
issn = "2521-327X",
publisher = "Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften",

}

RIS

TY - JOUR

T1 - Conditional work statistics of quantum measurements

AU - Mohammady, Mohammad

AU - Romito, Alessandro

PY - 2019/8/19

Y1 - 2019/8/19

N2 - In this paper we introduce a definition for conditional energy changes due to general quantum measurements, as the change in the conditional energy evaluated before, and after, the measurement process. By imposing minimal physical requirements on these conditional energies, we show that the most general expression for the conditional energy after the measurement is simply the expected value of the Hamiltonian given the post-measurement state. Conversely, the conditional energy before the measurement process is shown to be given by the real component of the weak value of the Hamiltonian. Our definition generalises well-known notions of distributions of internal energy change, such as that given by stochastic thermodynamics. By determining the conditional energy change of both system and measurement apparatus, we obtain the full conditional work statistics of quantum measurements, and show that this vanishes for all measurement outcomes if the measurement process conserves the total energy. Additionally, by incorporating the measurement process within a cyclic heat engine, we quantify the non-recoverable work due to measurements. This is shown to always be non-negative, thus satisfying the second law, and will be independent of the apparatus specifics for two classes of projective measurements.

AB - In this paper we introduce a definition for conditional energy changes due to general quantum measurements, as the change in the conditional energy evaluated before, and after, the measurement process. By imposing minimal physical requirements on these conditional energies, we show that the most general expression for the conditional energy after the measurement is simply the expected value of the Hamiltonian given the post-measurement state. Conversely, the conditional energy before the measurement process is shown to be given by the real component of the weak value of the Hamiltonian. Our definition generalises well-known notions of distributions of internal energy change, such as that given by stochastic thermodynamics. By determining the conditional energy change of both system and measurement apparatus, we obtain the full conditional work statistics of quantum measurements, and show that this vanishes for all measurement outcomes if the measurement process conserves the total energy. Additionally, by incorporating the measurement process within a cyclic heat engine, we quantify the non-recoverable work due to measurements. This is shown to always be non-negative, thus satisfying the second law, and will be independent of the apparatus specifics for two classes of projective measurements.

U2 - 10.22331/q-2019-08-19-175

DO - 10.22331/q-2019-08-19-175

M3 - Journal article

VL - 3

SP - 175

EP - 191

JO - Quantum

JF - Quantum

SN - 2521-327X

ER -