鞭毛
纤毛
轴丝
机制(生物学)
推进
执行机构
仿生学
工程类
航空航天工程
纳米技术
物理
机械工程
计算机科学
生物
材料科学
人工智能
基因
细胞生物学
量子力学
生物化学
作者
Jiaqi Miao,Tieshan Zhang,Gen Li,Dong Guo,Siqi Sun,Rong Tan,Jiahai Shi,Yajing Shen
出处
期刊:Engineering
[Elsevier BV]
日期:2023-02-07
卷期号:23: 170-180
被引量:14
标识
DOI:10.1016/j.eng.2022.09.014
摘要
The unique motion styles of flagella and cilia (i.e., planar/helical waveform propulsion of flagella and two-dimensional (2D)/three-dimensional (3D) asymmetric ciliary beating), play a key role in many biological activities and inspire lots of bionic designs, especially miniature robotic systems. However, quite different to the fact in nature that microorganisms can evolve diverse motions from the homologous bio-structure (9 + 2 axoneme structure), current bionics can still not find an effective engineering solution to achieve such wisdom. Herein, by investigating the inner structure of flagella/cilia and their intrinsic driven mechanisms, we derive a unified physical model to describe the microtubules’ bending and the constructed external motions. Then, we propose a three-channel based tubular actuation concept and correspondingly fabricate an actuator via a rod-embedded casting process. By sequencing the actuation of each channel, our design can not only reproduce the diverse 2D/3D flagellar/ciliary motility in nature, but also extrapolate a variety of symmetry-breaking ciliary beating modes for effective propulsion at low Reynolds number. This study deepens our understanding of the propulsion mechanism of microorganisms and provides new inspirations for the design of biomimetic systems, which may find significant applications in a wide spectrum of engineering fields.
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