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Main Authors: Zamora, Santiago, Durão, Lisan M. M., Noronha, Flavio, Macrì, Tommaso
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2404.16119
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author Zamora, Santiago
Durão, Lisan M. M.
Noronha, Flavio
Macrì, Tommaso
author_facet Zamora, Santiago
Durão, Lisan M. M.
Noronha, Flavio
Macrì, Tommaso
contents The phenomenon of Anderson localization, occurring in a disordered medium, significantly influences the dynamics of quantum particles. A fascinating manifestation of this is the "quantum boomerang effect" (QBE), observed when a quantum particle, propelled with a finite initial velocity, reverses its average trajectory, eventually halting at its starting point. This effect has recently been demonstrated in an experiment replicating the quantum kicked-rotor model. This research delves into the classical analog of QBE. We uncover evidence of a similar effect in classical systems, characterized by the absence of typical diffusion processes. Our investigation encompasses both simplified probabilistic models and more complex phenomenological models that link classical with quantum mechanics. The results indicate that the boomerang effect is not confined to the quantum realm and may also be present in diverse systems exhibiting subdiffusive behavior.
format Preprint
id arxiv_https___arxiv_org_abs_2404_16119
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Boomerang effect in classical stochastic models
Zamora, Santiago
Durão, Lisan M. M.
Noronha, Flavio
Macrì, Tommaso
Disordered Systems and Neural Networks
Statistical Mechanics
The phenomenon of Anderson localization, occurring in a disordered medium, significantly influences the dynamics of quantum particles. A fascinating manifestation of this is the "quantum boomerang effect" (QBE), observed when a quantum particle, propelled with a finite initial velocity, reverses its average trajectory, eventually halting at its starting point. This effect has recently been demonstrated in an experiment replicating the quantum kicked-rotor model. This research delves into the classical analog of QBE. We uncover evidence of a similar effect in classical systems, characterized by the absence of typical diffusion processes. Our investigation encompasses both simplified probabilistic models and more complex phenomenological models that link classical with quantum mechanics. The results indicate that the boomerang effect is not confined to the quantum realm and may also be present in diverse systems exhibiting subdiffusive behavior.
title Boomerang effect in classical stochastic models
topic Disordered Systems and Neural Networks
Statistical Mechanics
url https://arxiv.org/abs/2404.16119