不稳定性
屈曲
材料科学
执行机构
软物质
机械
纳米技术
物理
计算机科学
工程类
复合材料
胶体
人工智能
化学工程
作者
Tonghui Zhao,Jiu‐an Lv
标识
DOI:10.1002/adma.202502434
摘要
Living tubular organs can spatiotemporally and cyclically deform their muscular walls to implement adaptable and sustainable peristaltic pumping applicable to broad matter, achieved via asymmetric and non-equilibrium self-oscillating deformations of muscular walls. However, man-made tubular soft actuators have been limited to pumping a few simple matters, because of their reciprocal and monotonic wall motions that cannot break time-reversal symmetry and system equilibrium to gain adaptable and sustainable pumping. Here, a phototunable Rayleigh 3D soft self-oscillator (PR3DSSO) capable of multimodal, nonreciprocal, self-sustainable wall deformations is presented. PR3DSSO's design leverages two direction-and-dimension-phototunable tubular instabilities: snapping and postbuckling. The post-buckling instability can generate local-wall origami which cannot only fold local walls into multimodal shape-mode waves, but also break wall-motion symmetry; snapping instabilities help break equilibrium in wall motions to initiate autonomous wall motions. These phototunable-instabilities-driven wall deformations unprecedentedly create Rayleigh-like 3D wall motions, which allow for versatile biomimetic tubular peristaltic pumping adapt to broad matter. Our PR3DSSO would spur creative life-like active-material designs and novel pumping functions.
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