纺纱
超声波传感器
材料科学
声学
声流
半径
超声波
推进
干扰(通信)
纳米技术
粒子(生态学)
物理
电气工程
计算机科学
航空航天工程
工程类
复合材料
海洋学
频道(广播)
地质学
计算机安全
作者
Qiang Gao,Zhou Yang,Ruitong Zhu,Jinping Wang,Pengzhao Xu,Jiayu Liu,Xiaowen Chen,Zuyao Yan,Yixin Peng,Yanping Wang,Hairong Zheng,Feiyan Cai,Wei Wang
出处
期刊:ACS Nano
[American Chemical Society]
日期:2023-02-23
卷期号:17 (5): 4729-4739
被引量:40
标识
DOI:10.1021/acsnano.2c11070
摘要
The ability to steer micromotors in specific directions and at precise speeds is highly desired for their use in complex environments. However, a generic steering strategy that can be applied to micromotors of all types and surface coatings is yet to be developed. Here, we report that ultrasound of ∼100 kHz can spin a spherical micromotor so that it turns left or right when moving forward, or that it moves in full circles. The direction and angular speeds of their spinning and the radii of circular trajectories are precisely tunable by varying ultrasound voltages and frequencies, as well as particle properties such as its radius, materials, and coating thickness. Such spinning is hypothesized to originate from the circular microstreaming flows localized around a solid microsphere vibrating in ultrasound. In addition to causing a micromotor to spin, such streaming flows also helped release cargos from a micromotor during a capture-transport-release mission. Localized microstreaming does not depend on or interference with a specific propulsion mechanism and can steer a wide variety of micromotors. This work suggests that ultrasound can be used to steer microrobots in complex, biologically relevant environments as well as to steer microorganisms and cells.
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