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Bibliographic Details
Main Authors: Akhouri, Unnati, Shandera, Sarah, Henry, Jackson
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.00116
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author Akhouri, Unnati
Shandera, Sarah
Henry, Jackson
author_facet Akhouri, Unnati
Shandera, Sarah
Henry, Jackson
contents We design several examples of constrained, symmetric quantum circuit dynamics that generate non-equilibrium steady states. The qubit networks maintain local memory of the initial conditions and display inhomogeneous subsystem dynamics over long times, clearly distinguishable from approximately thermalizing networks of the same size. Each network can be described as an ensemble of open systems, a collection of qubits evolving with phase-covariant dynamics. Constraints from the conservation law and global unitary dynamics of the entire network bound the distribution of single-qubit dynamics in the ensemble, but different steady states are distinguishable by several measures. We quantify the distance of the steady states from the homogeneous steady state and further characterize them using the complexity of their mutual information networks, the volume of state space explored, a thermodynamic utility measure using extractable work, and correlated structure in the occurrence of non-completely positive qubit propagator maps.
format Preprint
id arxiv_https___arxiv_org_abs_2505_00116
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Open-systems tools for non-thermalizing closed quantum systems
Akhouri, Unnati
Shandera, Sarah
Henry, Jackson
Quantum Physics
We design several examples of constrained, symmetric quantum circuit dynamics that generate non-equilibrium steady states. The qubit networks maintain local memory of the initial conditions and display inhomogeneous subsystem dynamics over long times, clearly distinguishable from approximately thermalizing networks of the same size. Each network can be described as an ensemble of open systems, a collection of qubits evolving with phase-covariant dynamics. Constraints from the conservation law and global unitary dynamics of the entire network bound the distribution of single-qubit dynamics in the ensemble, but different steady states are distinguishable by several measures. We quantify the distance of the steady states from the homogeneous steady state and further characterize them using the complexity of their mutual information networks, the volume of state space explored, a thermodynamic utility measure using extractable work, and correlated structure in the occurrence of non-completely positive qubit propagator maps.
title Open-systems tools for non-thermalizing closed quantum systems
topic Quantum Physics
url https://arxiv.org/abs/2505.00116