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Main Authors: Ahumada, Maritza, Valderrama-Quinteros, Natalia, Romero, Guillermo
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.07527
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author Ahumada, Maritza
Valderrama-Quinteros, Natalia
Romero, Guillermo
author_facet Ahumada, Maritza
Valderrama-Quinteros, Natalia
Romero, Guillermo
contents Periodically driving a quantum many-body system can drastically change its properties, leading to exotic non-equilibrium states of matter without a static analog. In this scenario, parametric resonances and the complexity of an interacting many-body system are pivotal in establishing non-equilibrium states. We report on a Floquet-engineered transverse field Ising model for the controlled propagation in one dimension of spin waves. The underlying mechanisms behind our proposal rely on high-frequency drivings using characteristic parametric resonances of the spin lattice. Many-body resonances modulating spin-spin exchange or individual spin gaps inhibit interactions between spins thus proving a mechanism for controlling spin-wave propagation and a quantum switch. Our schemes may be implemented in circuit QED with direct applications in coupling-decoupling schemes for system-reservoir interaction and routing in quantum networks.
format Preprint
id arxiv_https___arxiv_org_abs_2501_07527
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Floquet-engineered system-reservoir interaction in the transverse field Ising model
Ahumada, Maritza
Valderrama-Quinteros, Natalia
Romero, Guillermo
Quantum Physics
Periodically driving a quantum many-body system can drastically change its properties, leading to exotic non-equilibrium states of matter without a static analog. In this scenario, parametric resonances and the complexity of an interacting many-body system are pivotal in establishing non-equilibrium states. We report on a Floquet-engineered transverse field Ising model for the controlled propagation in one dimension of spin waves. The underlying mechanisms behind our proposal rely on high-frequency drivings using characteristic parametric resonances of the spin lattice. Many-body resonances modulating spin-spin exchange or individual spin gaps inhibit interactions between spins thus proving a mechanism for controlling spin-wave propagation and a quantum switch. Our schemes may be implemented in circuit QED with direct applications in coupling-decoupling schemes for system-reservoir interaction and routing in quantum networks.
title Floquet-engineered system-reservoir interaction in the transverse field Ising model
topic Quantum Physics
url https://arxiv.org/abs/2501.07527