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Main Authors: Wakahara, Yukinori, Uchida, Nariya
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.16705
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author Wakahara, Yukinori
Uchida, Nariya
author_facet Wakahara, Yukinori
Uchida, Nariya
contents We investigate synchronization and metachronal-wave formation in a one-dimensional array of eukaryotic flagella using an elastohydrodynamic model. In contrast to a two-flagellum system, where only in-phase synchronization is stable, larger arrays are found to support stable metachronal waves with finite phase differences. Direct numerical simulations show that metachronal waves appear with increasing probability as the number of flagella increases. To explain this many-body effect, we construct a phase description for the array from that of the pair problem and analyze the stability of phase-locked states with nearest-neighbor hydrodynamic coupling. The analysis shows that increasing system size enlarges the set of stable phase-locked modes, thereby promoting metachronal-wave selection. A continuum description further relates these collective states to advection and diffusion of the phase-difference field. These results provide a simple theoretical framework for understanding how hydrodynamic interactions generate robust metachronal waves in flagellar arrays.
format Preprint
id arxiv_https___arxiv_org_abs_2605_16705
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Synchronization and metachronal waves in an array of eukaryotic flagella
Wakahara, Yukinori
Uchida, Nariya
Adaptation and Self-Organizing Systems
We investigate synchronization and metachronal-wave formation in a one-dimensional array of eukaryotic flagella using an elastohydrodynamic model. In contrast to a two-flagellum system, where only in-phase synchronization is stable, larger arrays are found to support stable metachronal waves with finite phase differences. Direct numerical simulations show that metachronal waves appear with increasing probability as the number of flagella increases. To explain this many-body effect, we construct a phase description for the array from that of the pair problem and analyze the stability of phase-locked states with nearest-neighbor hydrodynamic coupling. The analysis shows that increasing system size enlarges the set of stable phase-locked modes, thereby promoting metachronal-wave selection. A continuum description further relates these collective states to advection and diffusion of the phase-difference field. These results provide a simple theoretical framework for understanding how hydrodynamic interactions generate robust metachronal waves in flagellar arrays.
title Synchronization and metachronal waves in an array of eukaryotic flagella
topic Adaptation and Self-Organizing Systems
url https://arxiv.org/abs/2605.16705