Theory of quantum energy transfer in spin chains: Superexchange and ballistic motion

Yu, Claire X.; Wu, Lian-Ao; Segal, Dvira

doi:10.1063/1.3668083

Cited by 2 publications

(2 citation statements)

References 54 publications

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“…It captures the main physics: Heat is exchanged in the σ x − σ z model due to the two reaction coordinates becoming effectively coupled through the spin, an effect reminiscent of "superexchange" for charge current 60,61 . Since the RCs are in fact part of the heat baths, this term corresponds to the direct, inter-bath current as described by Eq.…”

Section: ûLmentioning

confidence: 99%

“…As a result, the model manifests the emergence of two distinct transport regimes 56 : (i) The current flows sequentially from the hot to the cold reservoir mediated by the excitation of the central spin. (ii) Heat flows directly from the hot to the cold reservoir, apparently without exciting the central spin, in a manner reminiscent of the tunneling-superexchange behavior 60,61 . This direct bath-to-bath current between reservoirs in the generalized, non-commutative spin-boson model is an example of a transport phenomenon that emerges beyond second order in perturbation theory in the system-bath coupling energy.…”

Section: Introductionmentioning

confidence: 99%

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Quantum Thermal Transport Beyond Second Order with the Reaction Coordinate Mapping

Anto-Sztrikacs,

Ivander,

Segal

2022

Preprint

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Standard quantum master equation techniques such as the Redfield or Lindblad equations are perturbative to second order in the microscopic system-reservoir coupling parameter λ . As a result, characteristics of dissipative systems, which are beyond second order in λ , are not captured by such tools. Moreover, if the leading order in the studied effect is higher-than-quadratic in λ , a second-order description fundamentally fails even at weak coupling. Here, using the reaction coordinate (RC) quantum master equation framework, we are able to investigate and classify higherthan-second order transport mechanisms. This technique, which relies on the redefinition of the system-environment boundary, allows for the effects of system-bath coupling to be included to high orders. We study steady-state heat current beyond second-order in two models: The generalized spin-boson model with non-commuting system-bath operators and a three-level ladder system. In the latter model heat enters in one transition and it is extracted from a different one. Crucially, we identify two transport pathways: (i) System's current, where heat conduction is mediated by transitions in the system, with the heat current scaling as j q ∝ λ 2 to lowest order in λ . (ii) Inter-bath current, with the thermal baths directly exchanging energy between them, facilitated by the bridging quantum system. To the lowest order in λ , this current scales as j q ∝ λ 4 . These mechanisms are uncovered and examined using numerical and analytical tools. We contend that the RC mapping brings already at the level of the mapped Hamiltonian much insights on transport characteristics.

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Section: ûLmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Quantum Thermal Transport Beyond Second Order with the Reaction Coordinate Mapping

Anto-Sztrikacs,

Ivander,

Segal

2022

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

Quantum thermal transport beyond second order with the reaction coordinate mapping

Anto-Sztrikacs

Ivander

Segal

2022

The Journal of Chemical Physics

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Standard quantum master equation techniques, such as the Redfield or Lindblad equations, are perturbative to second order in the microscopic system–reservoir coupling parameter λ. As a result, the characteristics of dissipative systems, which are beyond second order in λ, are not captured by such tools. Moreover, if the leading order in the studied effect is higher-than-quadratic in λ, a second-order description fundamentally fails even at weak coupling. Here, using the reaction coordinate (RC) quantum master equation framework, we are able to investigate and classify higher-than-second-order transport mechanisms. This technique, which relies on the redefinition of the system–environment boundary, allows for the effects of system–bath coupling to be included to high orders. We study steady-state heat current beyond second-order in two models: The generalized spin-boson model with non-commuting system–bath operators and a three-level ladder system. In the latter model, heat enters in one transition and is extracted from a different one. Crucially, we identify two transport pathways: (i) System’s current, where heat conduction is mediated by transitions in the system, with the heat current scaling as j q ∝ λ2 to the lowest order in λ. (ii) Inter-bath current, with the thermal baths directly exchanging energy between them, facilitated by the bridging quantum system. To the lowest order in λ, this current scales as j q ∝ λ4. These mechanisms are uncovered and examined using numerical and analytical tools. We contend that the RC mapping brings, already at the level of the mapped Hamiltonian, much insight into transport characteristics.

show abstract

Theory of quantum energy transfer in spin chains: Superexchange and ballistic motion

Cited by 2 publications

References 54 publications

Quantum Thermal Transport Beyond Second Order with the Reaction Coordinate Mapping

Quantum Thermal Transport Beyond Second Order with the Reaction Coordinate Mapping

Quantum thermal transport beyond second order with the reaction coordinate mapping

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