4D Thermomechanical metamaterials for soft microrobotics

Qingxiang Ji; Johnny Moughames; Xueyan Chen; Guodong Fang; Juan J. Huaroto; Vincent Laude; Julio Andrés Iglesias Martínez; Gwenn Ulliac; Cédric Clévy; Philippe Lutz; Kanty Rabenorosoa; Valerian Guelpa; Arnaud Spangenberg; Jun Liang; Alexis Mosset; Muamer Kadic

doi:10.1038/s43246-021-00189-0

4D Thermomechanical metamaterials for soft microrobotics

Qingxiang Ji, Johnny Moughames, Xueyan Chen, Guodong Fang, Juan J. Huaroto, Vincent Laude, Julio Andrés Iglesias Martínez, Gwenn Ulliac, Cédric Clévy, Philippe Lutz, Kanty Rabenorosoa, Valerian Guelpa, Arnaud Spangenberg, Jun Liang^*, Alexis Mosset, Muamer Kadic^*

^*Corresponding author for this work

Institute of Advanced Structure Technology

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

26 Citations (Scopus)

Abstract

Metamaterials have attracted wide scientific interest to break fundamental bounds on materials properties. Recently, the field has been extending to coupled physical phenomena where one physics acts as the driving force for another. Stimuli-responsive or 4D metamaterials have been demonstrated for thermo-elasticity, magneto-optics or piezo-electricity. Herein, a soft, ultra-compact and accurate microrobot is described which can achieve controlled motion under thermal stimuli. The system consists of an organized assembly of two functional structures: a rotational and a translational element. Both elements are designed basing upon the principle of the thermoelastic bilayer plate that bends as temperature changes. Samples are fabricated using gray-tone lithography from a single polymer but with two different laser writing powers, making each part different in its thermal and mechanical behaviors. Excellent motion-controllable, reversible and stable features in a dry environment are verified by simulations and experiments, revealing broad application prospects for the designed soft micro actuators.

Original language	English
Article number	93
Journal	Communications Materials
Volume	2
Issue number	1
DOIs	https://doi.org/10.1038/s43246-021-00189-0
Publication status	Published - Dec 2021

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title = "4D Thermomechanical metamaterials for soft microrobotics",

abstract = "Metamaterials have attracted wide scientific interest to break fundamental bounds on materials properties. Recently, the field has been extending to coupled physical phenomena where one physics acts as the driving force for another. Stimuli-responsive or 4D metamaterials have been demonstrated for thermo-elasticity, magneto-optics or piezo-electricity. Herein, a soft, ultra-compact and accurate microrobot is described which can achieve controlled motion under thermal stimuli. The system consists of an organized assembly of two functional structures: a rotational and a translational element. Both elements are designed basing upon the principle of the thermoelastic bilayer plate that bends as temperature changes. Samples are fabricated using gray-tone lithography from a single polymer but with two different laser writing powers, making each part different in its thermal and mechanical behaviors. Excellent motion-controllable, reversible and stable features in a dry environment are verified by simulations and experiments, revealing broad application prospects for the designed soft micro actuators.",

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doi = "10.1038/s43246-021-00189-0",

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AU - Ji, Qingxiang

AU - Moughames, Johnny

AU - Chen, Xueyan

AU - Fang, Guodong

AU - Huaroto, Juan J.

AU - Laude, Vincent

AU - Martínez, Julio Andrés Iglesias

AU - Ulliac, Gwenn

AU - Clévy, Cédric

AU - Lutz, Philippe

AU - Rabenorosoa, Kanty

AU - Guelpa, Valerian

AU - Spangenberg, Arnaud

AU - Liang, Jun

AU - Mosset, Alexis

AU - Kadic, Muamer

PY - 2021/12

Y1 - 2021/12

N2 - Metamaterials have attracted wide scientific interest to break fundamental bounds on materials properties. Recently, the field has been extending to coupled physical phenomena where one physics acts as the driving force for another. Stimuli-responsive or 4D metamaterials have been demonstrated for thermo-elasticity, magneto-optics or piezo-electricity. Herein, a soft, ultra-compact and accurate microrobot is described which can achieve controlled motion under thermal stimuli. The system consists of an organized assembly of two functional structures: a rotational and a translational element. Both elements are designed basing upon the principle of the thermoelastic bilayer plate that bends as temperature changes. Samples are fabricated using gray-tone lithography from a single polymer but with two different laser writing powers, making each part different in its thermal and mechanical behaviors. Excellent motion-controllable, reversible and stable features in a dry environment are verified by simulations and experiments, revealing broad application prospects for the designed soft micro actuators.

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4D Thermomechanical metamaterials for soft microrobotics

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