Light-responsive hydrogel microcrawlers, powered and steered with spatially homogeneous illumination

Jindrich Kropacek; Charlie Maslen; Paolo Gidoni; Petr Cigler; Frantisek Stepanek; Ivan Rehor

doi:10.1089/soro.2023.0074

Light-responsive hydrogel microcrawlers, powered and steered with spatially homogeneous illumination

Jindrich Kropacek, Charlie Maslen, Paolo Gidoni, Petr Cigler, Frantisek Stepanek, Ivan Rehor

Pure And Applied Chemistry

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

3 Citations (Scopus)

1 Downloads (Pure)

Abstract

Sub-millimeter untethered locomoting robots hold promise to radically change multiple areas of human activity such as microfabrication/assembly or health care. To overcome the associated hurdles of such a degree of robot miniaturization, radically new approaches are being adopted, often relying on soft actuating polymeric materials. Here, we present light-driven, crawling microrobots that locomote by a single degree of freedom actuation of their light-responsive tail section. The direction of locomotion is dictated by the robot body design and independent of the spatial modulation of the light stimuli, allowing simultaneous multidirectional motion of multiple robots. Moreover, we present a method for steering such robots by reversibly deforming their front section, using ultraviolet (UV) light as a trigger. The deformation dictates the robot locomotion, performing right- or left-hand turning when the UV is turned on or off respectively. The robots' motion and navigation are not coupled to the position of the light sources, which enables simultaneous locomotion of multiple robots, steering of robots and brings about flexibility with the methods to deliver the light to the place of robot operation.

Original language	English
Pages (from-to)	531-538
Number of pages	8
Journal	Soft Robotics
Volume	11
Issue number	3
DOIs	https://doi.org/10.1089/soro.2023.0074
Publication status	Published - 20 Jun 2024

Funding

I.R. acknowledges GACR Grant no. 23-05908K. The work of P.C. was supported by Ministry of Education, Youth, and Sports of the Czech Republic (project no. CZ.02.01.01/00/22_008/0004558, co-funded by the European Union). P.G. acknowledges the GAČR Junior Star Grant 21-09732M, and I.R. acknowledges the UCT Dagmar Prochazkova starting grant.

Keywords

hydrogel
robotic soft material
robotics
soft robotics

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10.1089/soro.2023.0074

Kropacek-etal-SR-2024-Light-responsive-hydrogel-microcrawlersAccepted author manuscript, 2.21 MBLicence: Strath_1

Cite this

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title = "Light-responsive hydrogel microcrawlers, powered and steered with spatially homogeneous illumination",

abstract = "Sub-millimeter untethered locomoting robots hold promise to radically change multiple areas of human activity such as microfabrication/assembly or health care. To overcome the associated hurdles of such a degree of robot miniaturization, radically new approaches are being adopted, often relying on soft actuating polymeric materials. Here, we present light-driven, crawling microrobots that locomote by a single degree of freedom actuation of their light-responsive tail section. The direction of locomotion is dictated by the robot body design and independent of the spatial modulation of the light stimuli, allowing simultaneous multidirectional motion of multiple robots. Moreover, we present a method for steering such robots by reversibly deforming their front section, using ultraviolet (UV) light as a trigger. The deformation dictates the robot locomotion, performing right- or left-hand turning when the UV is turned on or off respectively. The robots' motion and navigation are not coupled to the position of the light sources, which enables simultaneous locomotion of multiple robots, steering of robots and brings about flexibility with the methods to deliver the light to the place of robot operation.",

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author = "Jindrich Kropacek and Charlie Maslen and Paolo Gidoni and Petr Cigler and Frantisek Stepanek and Ivan Rehor",

note = "This is the accepted version of the following article: Kropacek, J, Maslen, C, Gidoni, P, Cigler, P, Stepanek, F & Rehor, I 2024, 'Light-responsive hydrogel microcrawlers, powered and steered with spatially homogeneous illumination', Soft Robotics, vol. 11, no. 3, pp. 531-538. It has now been formally published in final form at Soft Robotics at https://doi.org/10.1089/soro.2023.0074. This original submission version of the article may be used for non-commercial purposes in accordance with the Mary Ann Liebert, Inc., publishers{\textquoteright} self-archiving terms and conditions.",

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language = "English",

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AU - Stepanek, Frantisek

AU - Rehor, Ivan

N1 - This is the accepted version of the following article: Kropacek, J, Maslen, C, Gidoni, P, Cigler, P, Stepanek, F & Rehor, I 2024, 'Light-responsive hydrogel microcrawlers, powered and steered with spatially homogeneous illumination', Soft Robotics, vol. 11, no. 3, pp. 531-538. It has now been formally published in final form at Soft Robotics at https://doi.org/10.1089/soro.2023.0074. This original submission version of the article may be used for non-commercial purposes in accordance with the Mary Ann Liebert, Inc., publishers’ self-archiving terms and conditions.

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N2 - Sub-millimeter untethered locomoting robots hold promise to radically change multiple areas of human activity such as microfabrication/assembly or health care. To overcome the associated hurdles of such a degree of robot miniaturization, radically new approaches are being adopted, often relying on soft actuating polymeric materials. Here, we present light-driven, crawling microrobots that locomote by a single degree of freedom actuation of their light-responsive tail section. The direction of locomotion is dictated by the robot body design and independent of the spatial modulation of the light stimuli, allowing simultaneous multidirectional motion of multiple robots. Moreover, we present a method for steering such robots by reversibly deforming their front section, using ultraviolet (UV) light as a trigger. The deformation dictates the robot locomotion, performing right- or left-hand turning when the UV is turned on or off respectively. The robots' motion and navigation are not coupled to the position of the light sources, which enables simultaneous locomotion of multiple robots, steering of robots and brings about flexibility with the methods to deliver the light to the place of robot operation.

AB - Sub-millimeter untethered locomoting robots hold promise to radically change multiple areas of human activity such as microfabrication/assembly or health care. To overcome the associated hurdles of such a degree of robot miniaturization, radically new approaches are being adopted, often relying on soft actuating polymeric materials. Here, we present light-driven, crawling microrobots that locomote by a single degree of freedom actuation of their light-responsive tail section. The direction of locomotion is dictated by the robot body design and independent of the spatial modulation of the light stimuli, allowing simultaneous multidirectional motion of multiple robots. Moreover, we present a method for steering such robots by reversibly deforming their front section, using ultraviolet (UV) light as a trigger. The deformation dictates the robot locomotion, performing right- or left-hand turning when the UV is turned on or off respectively. The robots' motion and navigation are not coupled to the position of the light sources, which enables simultaneous locomotion of multiple robots, steering of robots and brings about flexibility with the methods to deliver the light to the place of robot operation.

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Light-responsive hydrogel microcrawlers, powered and steered with spatially homogeneous illumination

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