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Main Authors: Jin, Tony, Ferreira, João, Bauer, Michel, Filippone, Michele, Giamarchi, Thierry
Format: Preprint
Published: 2022
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Online Access:https://arxiv.org/abs/2206.13985
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author Jin, Tony
Ferreira, João
Bauer, Michel
Filippone, Michele
Giamarchi, Thierry
author_facet Jin, Tony
Ferreira, João
Bauer, Michel
Filippone, Michele
Giamarchi, Thierry
contents We devise a semi-classical model to describe the transport properties of low-dimensional fermionic lattices under the influence of external quantum stochastic noise. These systems behave as quantum stochastic resistors, where the bulk particle transport is diffusive and obeys the Ohm/Fick's law. Here, we extend previous exact studies beyond the one-dimensional limit to ladder geometries and explore different dephasing mechanisms that are relevant to different physical systems, from solid-state to cold atoms. We find a non-trivial dependence of the conductance of these systems on the chemical potential of the reservoirs. We then introduce a semi-classical approach that is in good agreement with the exact numerical solution and provides an intuitive and simpler interpretation of transport in quantum stochastic resistors. Moreover, we find that the conductance of quantum ladders is insensitive to the coherence of the dephasing process along the direction transverse to transport, despite the fact that the system reaches different stationary states. We conclude by discussing the case of dissipative leads affected by dephasing, deriving the conditions for which they effectively behave as Markovian injectors of particles in the system.
format Preprint
id arxiv_https___arxiv_org_abs_2206_13985
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Semi-classical theory of quantum stochastic resistors
Jin, Tony
Ferreira, João
Bauer, Michel
Filippone, Michele
Giamarchi, Thierry
Statistical Mechanics
We devise a semi-classical model to describe the transport properties of low-dimensional fermionic lattices under the influence of external quantum stochastic noise. These systems behave as quantum stochastic resistors, where the bulk particle transport is diffusive and obeys the Ohm/Fick's law. Here, we extend previous exact studies beyond the one-dimensional limit to ladder geometries and explore different dephasing mechanisms that are relevant to different physical systems, from solid-state to cold atoms. We find a non-trivial dependence of the conductance of these systems on the chemical potential of the reservoirs. We then introduce a semi-classical approach that is in good agreement with the exact numerical solution and provides an intuitive and simpler interpretation of transport in quantum stochastic resistors. Moreover, we find that the conductance of quantum ladders is insensitive to the coherence of the dephasing process along the direction transverse to transport, despite the fact that the system reaches different stationary states. We conclude by discussing the case of dissipative leads affected by dephasing, deriving the conditions for which they effectively behave as Markovian injectors of particles in the system.
title Semi-classical theory of quantum stochastic resistors
topic Statistical Mechanics
url https://arxiv.org/abs/2206.13985