Light-steered locomotion of muscle-like hydrogel by self-coordinated shape change and friction modulation

Zhu, Qing; Du, Cong; Dai, Yahao; Daab, Matthias; Matejdes, Marián; Breu, Josef; Hong, Wei; Zheng, Qiang; Wu, Zi Liang

doi:10.1038/s41467-020-18801-1

Cited by 165 publications

(162 citation statements)

References 58 publications

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“…attract extensive interests because of their promising applications in molecular separation, [4] medical dressings, [5] soft actuators, [6,7] flexible electronics, [8,9] etc. For example, using soft and stretchable materials as the substrate of flexible electronics requires the hydrogels to have robust mechanical performances, suitable thickness, and good compliance to wrap on target objects/organs with complex geometries.…”

Section: Doi: 101002/smll202103836mentioning

confidence: 99%

Engineering Tough Metallosupramolecular Hydrogel Films with Kirigami Structures for Compliant Soft Electronics

Hao

Zhang

et al. 2021

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A simple and effective approach is demonstrated to fabricate tough metallosupramolecular hydrogel films of poly(acrylic acid) by one‐pot photopolymerization of the precursor solution in the presence of Zr4+ ions that form coordination complexes with the carboxyl groups and serve as the physical crosslinks of the matrix. Both as‐prepared and equilibrated hydrogel films are transparent, tough, and stable over a wide range of temperature, ionic strength, and pH. The thickness of the films can be easily tailored with minimum value of ≈7 μm. Owing to the fast polymerization and gelation process, kirigami structures can be facilely encoded to the gel films by photolithographic polymerization, affording versatile functions such as additional stretchability and better compliance of the planar films to encapsulate objects with sophisticated geometries that are important for the design of soft electronics. By stencil printing of liquid metal on the hydrogel film with a kirigami structure, the integrated soft electronics shows good compliance to cover curved surfaces and high sensitivity to monitor human motions. Furthermore, this strategy is applied to diverse natural and synthetic macromolecules containing carboxyl groups to develop tough hydrogel films, which will open opportunities for the applications of hydrogel films in biomedical and engineering fields.

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Section: Doi: 101002/smll202103836mentioning

confidence: 99%

Engineering Tough Metallosupramolecular Hydrogel Films with Kirigami Structures for Compliant Soft Electronics

Hao

Zhang

et al. 2021

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“…Photons emitted by a light source and absorbed by a photoactive agent may produce mechanical motions by 1) photothermal expansion; [ 78,79 ] 2) conformational change; [ 80,81 ] or 3) phase transition (e.g., glass transition of shape‐memory materials, [ 82,83 ] nematic‐isotropic transition of liquid crystals, [ 84,85 ] and hydrophilic–hydrophobic transition of hydrogels. [ 86,87 ] )…”

Section: Plasmonic Nanostructures Tailored For Specific Applicationsmentioning

confidence: 99%

Plasmonic Nanostructures for Photothermal Conversion

et al. 2021

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The nonradiative conversion of light to heat by plasmonic nanostructures, the so‐called plasmonic photothermal effect, has attracted enormous attention due to their widespread potential applications. Herein, the perspectives on the design and preparation of plasmonic nanostructures for light to heat or photothermal conversion are provided. The general principle of plasmonic photothermal conversion is first introduced, and then, the strategies for improving efficiency are discussed, which is the focus of this field. Then, five typical application types are used, including solar energy harvesting, photothermal actuation, photothermal therapy, laser‐induced color printing, and high‐temperature photothermal devices, to elucidate how to tailor the nanomaterials to meet the requirements of these specific applications. In addition to the photothermal effect, other unique physical and chemical properties are coupled to further explore the application scenarios of plasmonic photothermal materials. Finally, a summary and the perspectives on the directions that may lead to the future development of this exciting field are also given.

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“…In addition, the anisotropic structure of actuating hydrogels can also be endowed with and coded by electrostatic repulsion during the fabrication process. 21,51,52,70,71 For example, Aida and coworkers developed an innovative actuating hydrogel with oriented electrolyte nanosheets. 51 The actuating hydrogel was polymerized from a NIPAm hydrogel precursor and contained titanate(IV) nanosheets (TiNSs).…”

Section: Anisotropy Produced During Fabricationmentioning

confidence: 99%

“…Compared with other shape deformation materials such as shape memory alloys 16 and liquid crystalline actuators, 17 shape transformation hydrogels can provide larger-scale deformation due to their so and wet properties. 18,19 Therefore, shape deformation hydrogels have attracted tremendous attention and shown potential applications in so robots, 20,21 biomimetic devices 22,23 and intelligent valves. 24,25 Shape deformation hydrogels can be divided into two types based on the shape deformation direction.…”

Section: Introductionmentioning

confidence: 99%

Recent progress in the shape deformation of polymeric hydrogels from memory to actuation

et al. 2021

Chem. Sci.

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Light-steered locomotion of muscle-like hydrogel by self-coordinated shape change and friction modulation

Cited by 165 publications

References 58 publications

Engineering Tough Metallosupramolecular Hydrogel Films with Kirigami Structures for Compliant Soft Electronics

Engineering Tough Metallosupramolecular Hydrogel Films with Kirigami Structures for Compliant Soft Electronics

Plasmonic Nanostructures for Photothermal Conversion

Recent progress in the shape deformation of polymeric hydrogels from memory to actuation

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