Nonequilibrium quantum heat transport between structured environments
Abstract
We apply the hierarchical equations of motion technique to analyzing nonequilibrium heat transport in a spin-boson type model, whereby heat transfer through a central spin is mediated by an intermediate pair of coupled harmonic oscillators. The coupling between each pair of oscillators is shown to introduce a localized gap into the effective spectral densities characterizing the system-oscillator-reservoir interactions. Compared to the case of a single mediating oscillator, we find the heat current to be drastically modified at weak system-bath coupling. In particular, a second-order treatment fails to capture the correct steady-state behavior in this regime, which stems from the -scaling of the energy transfer rate to lowest order in the coupling strength . This leads naturally to a strong suppression in the steady-state current in the asymptotically weak coupling limit. On the other hand, the current noise follows the same scaling as in the single oscillator case in accordance with the fluctuation-dissipation theorem. Additionally, we find the heat current to be consistent with Fourier's law even at large temperature bias. Our analysis highlights a novel mechanism for controlling heat transport in nanoscale systems based on tailoring the spectral properties of thermal environments.
Cite
@article{arxiv.2403.13904,
title = {Nonequilibrium quantum heat transport between structured environments},
author = {Graeme Pleasance and Francesco Petruccione},
journal= {arXiv preprint arXiv:2403.13904},
year = {2024}
}
Comments
18 + 10 pages, 7 figures, accepted version