Quantum heat engines: Limit cycles and exceptional points

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Quantum heat engines: Limit cycles and exceptional points. / Insinga, Andrea; Andresen, Bjarne; Salamon, Peter; Kosloff, Ronnie.

In: Physical Review E, Vol. 97, No. 6, 062153, 2018.

Research output: Contribution to journalJournal article – Annual report year: 2018Researchpeer-review

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Insinga, Andrea ; Andresen, Bjarne ; Salamon, Peter ; Kosloff, Ronnie. / Quantum heat engines: Limit cycles and exceptional points. In: Physical Review E. 2018 ; Vol. 97, No. 6.

Bibtex

@article{afd30191ea894cbd889a778d0a8c5bd0,
title = "Quantum heat engines: Limit cycles and exceptional points",
abstract = "We show that the inability of a quantum Otto cycle to reach a limit cycle is connected with the propagator of the cycle being noncompact. For a working fluid consisting of quantum harmonic oscillators, the transition point in parameter space where this instability occurs is associated with a non-Hermitian degeneracy (exceptional point) of the eigenvalues of the propagator. In particular, a third-order exceptional point is observed at the transition from the region where the eigenvalues are complex numbers to the region where all the eigenvalues are real. Within this region we find another exceptional point, this time of second order, at which the trajectory becomes divergent. The onset of the divergent behavior corresponds to the modulus of one of the eigenvalues becoming larger than one. The physical origin of this phenomenon is that the hot and cold heat baths are unable to dissipate the frictional internal heat generated in the adiabatic strokes of the cycle. This behavior is contrasted with that of quantum spins as working fluid which have a compact Hamiltonian and thus no exceptional points. All arguments are rigorously proved in terms of the systems' associated Lie algebras.",
author = "Andrea Insinga and Bjarne Andresen and Peter Salamon and Ronnie Kosloff",
year = "2018",
doi = "10.1103/PhysRevE.97.062153",
language = "English",
volume = "97",
journal = "Physical Review E (Statistical, Nonlinear, and Soft Matter Physics)",
issn = "2470-0045",
publisher = "American Physical Society",
number = "6",

}

RIS

TY - JOUR

T1 - Quantum heat engines: Limit cycles and exceptional points

AU - Insinga, Andrea

AU - Andresen, Bjarne

AU - Salamon, Peter

AU - Kosloff, Ronnie

PY - 2018

Y1 - 2018

N2 - We show that the inability of a quantum Otto cycle to reach a limit cycle is connected with the propagator of the cycle being noncompact. For a working fluid consisting of quantum harmonic oscillators, the transition point in parameter space where this instability occurs is associated with a non-Hermitian degeneracy (exceptional point) of the eigenvalues of the propagator. In particular, a third-order exceptional point is observed at the transition from the region where the eigenvalues are complex numbers to the region where all the eigenvalues are real. Within this region we find another exceptional point, this time of second order, at which the trajectory becomes divergent. The onset of the divergent behavior corresponds to the modulus of one of the eigenvalues becoming larger than one. The physical origin of this phenomenon is that the hot and cold heat baths are unable to dissipate the frictional internal heat generated in the adiabatic strokes of the cycle. This behavior is contrasted with that of quantum spins as working fluid which have a compact Hamiltonian and thus no exceptional points. All arguments are rigorously proved in terms of the systems' associated Lie algebras.

AB - We show that the inability of a quantum Otto cycle to reach a limit cycle is connected with the propagator of the cycle being noncompact. For a working fluid consisting of quantum harmonic oscillators, the transition point in parameter space where this instability occurs is associated with a non-Hermitian degeneracy (exceptional point) of the eigenvalues of the propagator. In particular, a third-order exceptional point is observed at the transition from the region where the eigenvalues are complex numbers to the region where all the eigenvalues are real. Within this region we find another exceptional point, this time of second order, at which the trajectory becomes divergent. The onset of the divergent behavior corresponds to the modulus of one of the eigenvalues becoming larger than one. The physical origin of this phenomenon is that the hot and cold heat baths are unable to dissipate the frictional internal heat generated in the adiabatic strokes of the cycle. This behavior is contrasted with that of quantum spins as working fluid which have a compact Hamiltonian and thus no exceptional points. All arguments are rigorously proved in terms of the systems' associated Lie algebras.

U2 - 10.1103/PhysRevE.97.062153

DO - 10.1103/PhysRevE.97.062153

M3 - Journal article

VL - 97

JO - Physical Review E (Statistical, Nonlinear, and Soft Matter Physics)

JF - Physical Review E (Statistical, Nonlinear, and Soft Matter Physics)

SN - 2470-0045

IS - 6

M1 - 062153

ER -