Electronically configurable microscopic metasheet robots

Qingkun Liu; Wei Wang; Himani Sinhmar; Itay Griniasty; Jason Z. Kim; Jacob T. Pelster; Paragkumar Chaudhari; Michael F. Reynolds; Michael C. Cao; David A. Muller; Alyssa B. Apsel; Nicholas L. Abbott; Hadas Kress-Gazit; Paul L. McEuen; Itai Cohen

doi:10.1038/s41563-024-02007-7

Electronically configurable microscopic metasheet robots

Qingkun Liu, Wei Wang, Himani Sinhmar, Itay Griniasty, Jason Z. Kim, Jacob T. Pelster, Paragkumar Chaudhari, Michael F. Reynolds, Michael C. Cao, David A. Muller, Alyssa B. Apsel, Nicholas L. Abbott, Hadas Kress-Gazit, Paul L. McEuen, Itai Cohen

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

Abstract

Shape morphing is vital to locomotion in microscopic organisms but has been challenging to achieve in sub-millimetre robots. By overcoming obstacles associated with miniaturization, we demonstrate microscopic electronically configurable morphing metasheet robots. These metabots expand locally using a kirigami structure spanning five decades in length, from 10 nm electrochemically actuated hinges to 100 μm splaying panels making up the ~1 mm robot. The panels are organized into unit cells that can expand and contract by 40% within 100 ms. These units are tiled to create metasheets with over 200 hinges and independent electronically actuating regions that enable the robot to switch between multiple target geometries with distinct curvature distributions. By electronically actuating independent regions with prescribed phase delays, we generate locomotory gaits. These results advance a metamaterial paradigm for microscopic, continuum, compliant, programmable robots and pave the way to a broad spectrum of applications, including reconfigurable micromachines, tunable optical metasurfaces and miniaturized biomedical devices.

Original language	English
Article number	eabq2296
Pages (from-to)	109-115
Number of pages	7
Journal	Nature Materials
Volume	24
Issue number	1
DOIs	https://doi.org/10.1038/s41563-024-02007-7
State	Published - Jan 2025
Externally published	Yes

All Science Journal Classification (ASJC) codes

General Chemistry
General Materials Science
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

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10.1038/s41563-024-02007-7

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title = "Electronically configurable microscopic metasheet robots",

abstract = "Shape morphing is vital to locomotion in microscopic organisms but has been challenging to achieve in sub-millimetre robots. By overcoming obstacles associated with miniaturization, we demonstrate microscopic electronically configurable morphing metasheet robots. These metabots expand locally using a kirigami structure spanning five decades in length, from 10 nm electrochemically actuated hinges to 100 μm splaying panels making up the ~1 mm robot. The panels are organized into unit cells that can expand and contract by 40% within 100 ms. These units are tiled to create metasheets with over 200 hinges and independent electronically actuating regions that enable the robot to switch between multiple target geometries with distinct curvature distributions. By electronically actuating independent regions with prescribed phase delays, we generate locomotory gaits. These results advance a metamaterial paradigm for microscopic, continuum, compliant, programmable robots and pave the way to a broad spectrum of applications, including reconfigurable micromachines, tunable optical metasurfaces and miniaturized biomedical devices.",

author = "Qingkun Liu and Wei Wang and Himani Sinhmar and Itay Griniasty and Kim, {Jason Z.} and Pelster, {Jacob T.} and Paragkumar Chaudhari and Reynolds, {Michael F.} and Cao, {Michael C.} and Muller, {David A.} and Apsel, {Alyssa B.} and Abbott, {Nicholas L.} and Hadas Kress-Gazit and McEuen, {Paul L.} and Itai Cohen",

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month = jan,

doi = "10.1038/s41563-024-02007-7",

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T1 - Electronically configurable microscopic metasheet robots

AU - Liu, Qingkun

AU - Wang, Wei

AU - Sinhmar, Himani

AU - Griniasty, Itay

AU - Kim, Jason Z.

AU - Pelster, Jacob T.

AU - Chaudhari, Paragkumar

AU - Reynolds, Michael F.

AU - Cao, Michael C.

AU - Muller, David A.

AU - Apsel, Alyssa B.

AU - Abbott, Nicholas L.

AU - Kress-Gazit, Hadas

AU - McEuen, Paul L.

AU - Cohen, Itai

PY - 2025/1

Y1 - 2025/1

N2 - Shape morphing is vital to locomotion in microscopic organisms but has been challenging to achieve in sub-millimetre robots. By overcoming obstacles associated with miniaturization, we demonstrate microscopic electronically configurable morphing metasheet robots. These metabots expand locally using a kirigami structure spanning five decades in length, from 10 nm electrochemically actuated hinges to 100 μm splaying panels making up the ~1 mm robot. The panels are organized into unit cells that can expand and contract by 40% within 100 ms. These units are tiled to create metasheets with over 200 hinges and independent electronically actuating regions that enable the robot to switch between multiple target geometries with distinct curvature distributions. By electronically actuating independent regions with prescribed phase delays, we generate locomotory gaits. These results advance a metamaterial paradigm for microscopic, continuum, compliant, programmable robots and pave the way to a broad spectrum of applications, including reconfigurable micromachines, tunable optical metasurfaces and miniaturized biomedical devices.

AB - Shape morphing is vital to locomotion in microscopic organisms but has been challenging to achieve in sub-millimetre robots. By overcoming obstacles associated with miniaturization, we demonstrate microscopic electronically configurable morphing metasheet robots. These metabots expand locally using a kirigami structure spanning five decades in length, from 10 nm electrochemically actuated hinges to 100 μm splaying panels making up the ~1 mm robot. The panels are organized into unit cells that can expand and contract by 40% within 100 ms. These units are tiled to create metasheets with over 200 hinges and independent electronically actuating regions that enable the robot to switch between multiple target geometries with distinct curvature distributions. By electronically actuating independent regions with prescribed phase delays, we generate locomotory gaits. These results advance a metamaterial paradigm for microscopic, continuum, compliant, programmable robots and pave the way to a broad spectrum of applications, including reconfigurable micromachines, tunable optical metasurfaces and miniaturized biomedical devices.

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DO - 10.1038/s41563-024-02007-7

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SN - 1476-1122

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JO - Nature Materials

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IS - 1

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ER -

Electronically configurable microscopic metasheet robots

Abstract

All Science Journal Classification (ASJC) codes

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