Related papers: The simplest 2D quantum walk detects chaoticity

The simplest 2D quantum walk detects chaoticity

URL: http://arxiv.org/abs/2501.13900v2
Date: Fri, 14 Feb 2025 18:55:45 GMT
Title: The simplest 2D quantum walk detects chaoticity
Authors: C. Alonso-Lobo, Gabriel G. Carlo, F. Borondo,
Abstract summary: We consider an extremely simple model consisting of alternate one-dimensional walks along the two spatial coordinates of bidimensional closed domains (hard wall billiards)<n>The chaotic or regular behavior that the shape of the boundary induces in the deterministic classical equations of motion and that translates into chaotic signatures for the quantized problem also results in sharp differences for the spectral statistics and morphology of the eigenfunctions of the quantum walker.
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License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Quantum walks have been actively studied from many perspectives, mainly from the statistical physics and quantum information points of view. We here determine the influence of basic chaotic features on the walker behavior. We consider an extremely simple model consisting of alternate one-dimensional walks along the two spatial coordinates of bidimensional closed domains (hard wall billiards). The chaotic or regular behavior that the shape of the boundary induces in the deterministic classical equations of motion and that translates into chaotic signatures for the quantized problem also results in sharp differences for the spectral statistics and morphology of the eigenfunctions of the quantum walker. This includes the presence of scarring on unstable periodic orbits of the Hamiltonian system. Unexpectedly, two different quantum mechanical problems share the same kind of features related to the corresponding classical dynamics of one of them.

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