Marangoni Effect-Driven Motion of Miniature Robots and Generation of Electricity on Water

Lidong Zhang; Yihui Yuan; Xiaxin Qiu; Ting Zhang; Qing Chen; Xinhua Huang

doi:10.1021/acs.langmuir.7b03270

Marangoni Effect-Driven Motion of Miniature Robots and Generation of Electricity on Water

Lidong Zhang^*
, Yihui Yuan
, Xiaxin Qiu
, Ting Zhang
, Qing Chen
, Xinhua Huang

^*此作品的通讯作者

化学与分子工程学院

East China Normal University
Anhui University of Science and Technology

科研成果: 期刊稿件 › 文章 › 同行评审

47 引用（Scopus）

摘要

The well-known Marangoni effect perfectly supports the dynamic mechanism of organic solvent-swollen gels on water. On this basis, we report a series of energy conversion processes of concentrated droplets of polyvinylidene fluoride/dimethyl formamide (PVDF/DMF) that can transfer chemical-free energy to kinetic energy to rapidly rotate itself on water. This droplet (22.2 mg) is capable to offer kinetic energy of 0.099 μJ to propel an artificial paper rocket of 31.8 mg to move over 560 cm on water at an initial velocity of 7.9 cm s^-1. As the droplet increases to 35.0 mg, a paper goldfish of 10.6 mg can be driven to swim longer at a higher initial velocity of 20 cm s^-1. The kinetic energy of the droplet can be further converted to electrical energy through an electromagnetic generator, in which as a 0.5 Mω resistor is loaded, the peak output reaches 6.5 mV that corresponds to the power density of 0.293 μW kg^-1. We believe that this report would open up a promising avenue to exploit energies for applications in miniature robotics.

源语言	英语
页（从-至）	12609-12615
页数	7
期刊	Langmuir
卷	33
期	44
DOI	https://doi.org/10.1021/acs.langmuir.7b03270
出版状态	已出版 - 7 11月 2017

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title = "Marangoni Effect-Driven Motion of Miniature Robots and Generation of Electricity on Water",

abstract = "The well-known Marangoni effect perfectly supports the dynamic mechanism of organic solvent-swollen gels on water. On this basis, we report a series of energy conversion processes of concentrated droplets of polyvinylidene fluoride/dimethyl formamide (PVDF/DMF) that can transfer chemical-free energy to kinetic energy to rapidly rotate itself on water. This droplet (22.2 mg) is capable to offer kinetic energy of 0.099 μJ to propel an artificial paper rocket of 31.8 mg to move over 560 cm on water at an initial velocity of 7.9 cm s-1. As the droplet increases to 35.0 mg, a paper goldfish of 10.6 mg can be driven to swim longer at a higher initial velocity of 20 cm s-1. The kinetic energy of the droplet can be further converted to electrical energy through an electromagnetic generator, in which as a 0.5 Mω resistor is loaded, the peak output reaches 6.5 mV that corresponds to the power density of 0.293 μW kg-1. We believe that this report would open up a promising avenue to exploit energies for applications in miniature robotics.",

author = "Lidong Zhang and Yihui Yuan and Xiaxin Qiu and Ting Zhang and Qing Chen and Xinhua Huang",

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T1 - Marangoni Effect-Driven Motion of Miniature Robots and Generation of Electricity on Water

AU - Zhang, Lidong

AU - Yuan, Yihui

AU - Qiu, Xiaxin

AU - Zhang, Ting

AU - Chen, Qing

AU - Huang, Xinhua

PY - 2017/11/7

Y1 - 2017/11/7

N2 - The well-known Marangoni effect perfectly supports the dynamic mechanism of organic solvent-swollen gels on water. On this basis, we report a series of energy conversion processes of concentrated droplets of polyvinylidene fluoride/dimethyl formamide (PVDF/DMF) that can transfer chemical-free energy to kinetic energy to rapidly rotate itself on water. This droplet (22.2 mg) is capable to offer kinetic energy of 0.099 μJ to propel an artificial paper rocket of 31.8 mg to move over 560 cm on water at an initial velocity of 7.9 cm s-1. As the droplet increases to 35.0 mg, a paper goldfish of 10.6 mg can be driven to swim longer at a higher initial velocity of 20 cm s-1. The kinetic energy of the droplet can be further converted to electrical energy through an electromagnetic generator, in which as a 0.5 Mω resistor is loaded, the peak output reaches 6.5 mV that corresponds to the power density of 0.293 μW kg-1. We believe that this report would open up a promising avenue to exploit energies for applications in miniature robotics.

AB - The well-known Marangoni effect perfectly supports the dynamic mechanism of organic solvent-swollen gels on water. On this basis, we report a series of energy conversion processes of concentrated droplets of polyvinylidene fluoride/dimethyl formamide (PVDF/DMF) that can transfer chemical-free energy to kinetic energy to rapidly rotate itself on water. This droplet (22.2 mg) is capable to offer kinetic energy of 0.099 μJ to propel an artificial paper rocket of 31.8 mg to move over 560 cm on water at an initial velocity of 7.9 cm s-1. As the droplet increases to 35.0 mg, a paper goldfish of 10.6 mg can be driven to swim longer at a higher initial velocity of 20 cm s-1. The kinetic energy of the droplet can be further converted to electrical energy through an electromagnetic generator, in which as a 0.5 Mω resistor is loaded, the peak output reaches 6.5 mV that corresponds to the power density of 0.293 μW kg-1. We believe that this report would open up a promising avenue to exploit energies for applications in miniature robotics.

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SN - 0743-7463

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JO - Langmuir

JF - Langmuir

IS - 44

ER -

Marangoni Effect-Driven Motion of Miniature Robots and Generation of Electricity on Water

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