Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Zhu, Jin, Qiao, Yateng, Yan, Lingchun, Zeng, Yan, Wu, Yibo, Bian, Hongyi, Huang, Yidi, Ye, Yuxin, Huang, Yingyue, Wei, Russell Hii Ching, Teng, Yinuo, Guo, Yunlong, Li, Gaojin, Qu, Zijie
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2407.16532
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866911964987392000
author Zhu, Jin
Qiao, Yateng
Yan, Lingchun
Zeng, Yan
Wu, Yibo
Bian, Hongyi
Huang, Yidi
Ye, Yuxin
Huang, Yingyue
Wei, Russell Hii Ching
Teng, Yinuo
Guo, Yunlong
Li, Gaojin
Qu, Zijie
author_facet Zhu, Jin
Qiao, Yateng
Yan, Lingchun
Zeng, Yan
Wu, Yibo
Bian, Hongyi
Huang, Yidi
Ye, Yuxin
Huang, Yingyue
Wei, Russell Hii Ching
Teng, Yinuo
Guo, Yunlong
Li, Gaojin
Qu, Zijie
contents Flagellated microorganisms overcome the low-Reynolds-number time reversibility by rotating helical flagella. For peritrichous bacteria, such as Escherichia coli, the randomly distributed flagellar filaments align along the same direction to form a bundle, facilitating complex locomotive strategies. To understand the process of flagella bundling, especially the propulsion force, we develop a multi-functional macroscopic experimental system and employ advanced numerical simulations for verification. Flagella arrangements and phase differences between helices are investigated, revealing the variation in propulsion contribution from the individual helix. Numerically, we build a time-dependent model to match the bundling process and study the influence of hydrodynamic interactions. Surprisingly, it is found that the total propulsion generated by a bundle of two filaments is constant at various phase differences between the helices. However, the difference between the propulsion from each helix is significantly affected by the phase difference, and only one of the helices is responsible for the total propulsion at a phase difference equals to pi. Through our experimental and computational results, we provide a new model considering the propulsion contribution of each filament to better understand microbial locomotion mechanisms, especially on the wobbling behavior of the cell. Our work also sheds light on the design and control of artificial microswimmers.
format Preprint
id arxiv_https___arxiv_org_abs_2407_16532
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Propulsion Contribution from Individual Filament in Flagellar Bundle
Zhu, Jin
Qiao, Yateng
Yan, Lingchun
Zeng, Yan
Wu, Yibo
Bian, Hongyi
Huang, Yidi
Ye, Yuxin
Huang, Yingyue
Wei, Russell Hii Ching
Teng, Yinuo
Guo, Yunlong
Li, Gaojin
Qu, Zijie
Soft Condensed Matter
Fluid Dynamics
Flagellated microorganisms overcome the low-Reynolds-number time reversibility by rotating helical flagella. For peritrichous bacteria, such as Escherichia coli, the randomly distributed flagellar filaments align along the same direction to form a bundle, facilitating complex locomotive strategies. To understand the process of flagella bundling, especially the propulsion force, we develop a multi-functional macroscopic experimental system and employ advanced numerical simulations for verification. Flagella arrangements and phase differences between helices are investigated, revealing the variation in propulsion contribution from the individual helix. Numerically, we build a time-dependent model to match the bundling process and study the influence of hydrodynamic interactions. Surprisingly, it is found that the total propulsion generated by a bundle of two filaments is constant at various phase differences between the helices. However, the difference between the propulsion from each helix is significantly affected by the phase difference, and only one of the helices is responsible for the total propulsion at a phase difference equals to pi. Through our experimental and computational results, we provide a new model considering the propulsion contribution of each filament to better understand microbial locomotion mechanisms, especially on the wobbling behavior of the cell. Our work also sheds light on the design and control of artificial microswimmers.
title Propulsion Contribution from Individual Filament in Flagellar Bundle
topic Soft Condensed Matter
Fluid Dynamics
url https://arxiv.org/abs/2407.16532