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Bibliographic Details
Main Authors: Tateyama, Yuta, Ito, Hiroaki, Komura, Shigeyuki, Kitahata, Hiroyuki
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2407.05742
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author Tateyama, Yuta
Ito, Hiroaki
Komura, Shigeyuki
Kitahata, Hiroyuki
author_facet Tateyama, Yuta
Ito, Hiroaki
Komura, Shigeyuki
Kitahata, Hiroyuki
contents We investigate the pattern dynamics of the one-dimensional nonreciprocal Swift-Hohenberg model. Characteristic spatiotemporal patterns such as disordered, aligned, swap, chiral-swap, and chiral phases emerge depending on the parameters. We classify the characteristic spatiotemporal patterns obtained in numerical simulation by focusing on the spatiotemporal Fourier spectrum of the order parameters. We derive a reduced dynamical system by using the spatial Fourier series expansion. We analyze the bifurcation structure around the fixed points corresponding to the aligned and chiral phases, and explain the transitions between them. The disordered phase is destabilized either to the aligned phase by the Turing bifurcation or to the chiral phase by the wave bifurcation, while the aligned phase and the chiral phase are connected by the pitchfork bifurcation.
format Preprint
id arxiv_https___arxiv_org_abs_2407_05742
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Pattern dynamics of the nonreciprocal Swift-Hohenberg model
Tateyama, Yuta
Ito, Hiroaki
Komura, Shigeyuki
Kitahata, Hiroyuki
Pattern Formation and Solitons
We investigate the pattern dynamics of the one-dimensional nonreciprocal Swift-Hohenberg model. Characteristic spatiotemporal patterns such as disordered, aligned, swap, chiral-swap, and chiral phases emerge depending on the parameters. We classify the characteristic spatiotemporal patterns obtained in numerical simulation by focusing on the spatiotemporal Fourier spectrum of the order parameters. We derive a reduced dynamical system by using the spatial Fourier series expansion. We analyze the bifurcation structure around the fixed points corresponding to the aligned and chiral phases, and explain the transitions between them. The disordered phase is destabilized either to the aligned phase by the Turing bifurcation or to the chiral phase by the wave bifurcation, while the aligned phase and the chiral phase are connected by the pitchfork bifurcation.
title Pattern dynamics of the nonreciprocal Swift-Hohenberg model
topic Pattern Formation and Solitons
url https://arxiv.org/abs/2407.05742