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Main Authors: Lawrence, Maggie, Pocrnic, Matthew, Fung, Erin, Carrasquilla, Juan, Gauger, Erik M., Segal, Dvira
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.09371
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author Lawrence, Maggie
Pocrnic, Matthew
Fung, Erin
Carrasquilla, Juan
Gauger, Erik M.
Segal, Dvira
author_facet Lawrence, Maggie
Pocrnic, Matthew
Fung, Erin
Carrasquilla, Juan
Gauger, Erik M.
Segal, Dvira
contents Carrier transport in quantum networks is governed by a variety of factors, including network dimensionality and connectivity, on-site energies, couplings between sites and whether they are short- or long-range, leakage processes, and environmental effects. In this work, we identify classes of quasi-one-dimensional chains with energy profiles that optimize carrier transport under such influences. Specifically, we optimize on-site energies using Optax's optimistic gradient descent and AdaMax algorithms, enabled by the JAX automatic differentiation framework. Focusing on nonequilibrium steady-state transport, we study the system's behavior under combined unitary and nonunitary (dephasing and dissipative) effects using the Lindblad quantum master equation. After validating our optimization scheme on short chains, we extend the study to larger systems where we identify systematic patterns in energy profiles. Our analysis reveals that different types of energy landscapes enhance transport, depending on whether inter-site tunneling couplings in the chain are short- or long-range, the existence of environmental interactions, and the temperature of the environment. Our classification and insights of optimal energy landscapes offer guidance for designing efficient transport systems for electronic, photovoltaic and quantum communication applications.
format Preprint
id arxiv_https___arxiv_org_abs_2508_09371
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Discovery of energy landscapes towards optimized quantum transport: Environmental effects and long-range tunneling
Lawrence, Maggie
Pocrnic, Matthew
Fung, Erin
Carrasquilla, Juan
Gauger, Erik M.
Segal, Dvira
Quantum Physics
Carrier transport in quantum networks is governed by a variety of factors, including network dimensionality and connectivity, on-site energies, couplings between sites and whether they are short- or long-range, leakage processes, and environmental effects. In this work, we identify classes of quasi-one-dimensional chains with energy profiles that optimize carrier transport under such influences. Specifically, we optimize on-site energies using Optax's optimistic gradient descent and AdaMax algorithms, enabled by the JAX automatic differentiation framework. Focusing on nonequilibrium steady-state transport, we study the system's behavior under combined unitary and nonunitary (dephasing and dissipative) effects using the Lindblad quantum master equation. After validating our optimization scheme on short chains, we extend the study to larger systems where we identify systematic patterns in energy profiles. Our analysis reveals that different types of energy landscapes enhance transport, depending on whether inter-site tunneling couplings in the chain are short- or long-range, the existence of environmental interactions, and the temperature of the environment. Our classification and insights of optimal energy landscapes offer guidance for designing efficient transport systems for electronic, photovoltaic and quantum communication applications.
title Discovery of energy landscapes towards optimized quantum transport: Environmental effects and long-range tunneling
topic Quantum Physics
url https://arxiv.org/abs/2508.09371