Reconfigurable multi-component micromachines driven by optoelectronic tweezers

Shuailong Zhang; Mohamed Elsayed; Ran Peng; Yujie Chen; Yanfeng Zhang; Jiaxi Peng; Weizhen Li; M. Dean Chamberlain; Adele Nikitina; Siyuan Yu; Xinyu Liu; Steven L. Neale; Aaron R. Wheeler

doi:10.1038/s41467-021-25582-8

Reconfigurable multi-component micromachines driven by optoelectronic tweezers

Shuailong Zhang, Mohamed Elsayed, Ran Peng, Yujie Chen, Yanfeng Zhang, Jiaxi Peng, Weizhen Li, M. Dean Chamberlain, Adele Nikitina, Siyuan Yu, Xinyu Liu, Steven L. Neale, Aaron R. Wheeler^*

^*Corresponding author for this work

School of Integrated Circuits and Electronics

Research output: Contribution to journal › Article › peer-review

59 Citations (Scopus)

Abstract

There is great interest in the development of micromotors which can convert energy to motion in sub-millimeter dimensions. Micromachines take the micromotor concept a step further, comprising complex systems in which multiple components work in concert to effectively realize complex mechanical tasks. Here we introduce light-driven micromotors and micromachines that rely on optoelectronic tweezers (OET). Using a circular micro-gear as a unit component, we demonstrate a range of new functionalities, including a touchless micro-feed-roller that allows the programming of precise three-dimensional particle trajectories, multi-component micro-gear trains that serve as torque- or velocity-amplifiers, and micro-rack-and-pinion systems that serve as microfluidic valves. These sophisticated systems suggest great potential for complex micromachines in the future, for application in microrobotics, micromanipulation, microfluidics, and beyond.

Original language	English
Article number	5349
Journal	Nature Communications
Volume	12
Issue number	1
DOIs	https://doi.org/10.1038/s41467-021-25582-8
Publication status	Published - 1 Dec 2021

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title = "Reconfigurable multi-component micromachines driven by optoelectronic tweezers",

abstract = "There is great interest in the development of micromotors which can convert energy to motion in sub-millimeter dimensions. Micromachines take the micromotor concept a step further, comprising complex systems in which multiple components work in concert to effectively realize complex mechanical tasks. Here we introduce light-driven micromotors and micromachines that rely on optoelectronic tweezers (OET). Using a circular micro-gear as a unit component, we demonstrate a range of new functionalities, including a touchless micro-feed-roller that allows the programming of precise three-dimensional particle trajectories, multi-component micro-gear trains that serve as torque- or velocity-amplifiers, and micro-rack-and-pinion systems that serve as microfluidic valves. These sophisticated systems suggest great potential for complex micromachines in the future, for application in microrobotics, micromanipulation, microfluidics, and beyond.",

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AU - Elsayed, Mohamed

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AU - Zhang, Yanfeng

AU - Peng, Jiaxi

AU - Li, Weizhen

AU - Chamberlain, M. Dean

AU - Nikitina, Adele

AU - Yu, Siyuan

AU - Liu, Xinyu

AU - Neale, Steven L.

AU - Wheeler, Aaron R.

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Reconfigurable multi-component micromachines driven by optoelectronic tweezers

Abstract

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