Recent advances in integration of 2D materials with soft matter for multifunctional robotic materials

Emerging soft robots with infinite degrees of freedom are one step closer to providing better human-machine interactions than conventional hard and stiff robots, attributing to their outstanding compliance/adaptability, evenly distributed stress, and programmable actuating behaviors. Soft matter ( e...

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Bibliographic Details
Published inMaterials horizons Vol. 7; no. 1; pp. 54 - 7
Main Authors Jing, Lin, Li, Kerui, Yang, Haitao, Chen, Po-Yen
Format Journal Article
LanguageEnglish
Published Cambridge Royal Society of Chemistry 01.01.2020
Subjects
Chemical properties
Crosslinking
Elastomers
Hydrogels
Matter & antimatter
Optical properties
Organic chemistry
Remote control
Remote sensing
Robotics
Robots
Stress concentration
Substrates
Two dimensional composites
Two dimensional materials
Wireless communications
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Summary:Emerging soft robots with infinite degrees of freedom are one step closer to providing better human-machine interactions than conventional hard and stiff robots, attributing to their outstanding compliance/adaptability, evenly distributed stress, and programmable actuating behaviors. Soft matter ( e.g. , hydrogels and elastomers) with high mechanical stability has been usually adopted for the fabrication of soft robots. However, soft matter exhibits limited optical, electrical, thermal, and chemical properties that restrict the development of functional soft robots. An emerging approach is to develop multifunctional robotic materials that are reconfigurable and can provide diverse built-in functions, such as wide-spectrum protection, tactile sensing, remote control, and wireless communication. To realize this approach, two-dimensional (2D) materials with diverse yet unique physicochemical properties have been recently integrated with soft matter to bring in add-on functionalities for fabricated soft robots. In this Minireview, we highlight three integration approaches for the fabrication of 2D material-soft matter robotic materials: (i) heterogenous blending of 2D materials within soft matter precursors followed by in situ crosslinking/curing; (ii) bilayer integration of 2D materials with soft matter substrates; and (iii) post-stabilization of 2D material (or 2D material-templated) architectures with elastomers. The advantages and drawbacks of each approach regarding the fabrication process and resulting characteristics are discussed in detail. The reversible actuating behaviors and built-in capabilities of the as-fabricated 2D material-soft matter composites, as well as their further applications as multifunctional robotic materials are summarized. Finally, current research gaps and future directions regarding the development of multifunctional robotic materials are addressed from our perspective by considering the design principles for future untethered soft robots. This Minireview highlights the pioneering advances in integration of 2D materials with soft matter for multifunctional robotic materials.
Bibliography:Po-Yen Chen is currently an assistant professor in the Department of Chemical and Biomolecular Engineering at the National University of Singapore (NUS). He completed his PhD in Chemical Engineering from the Massachusetts Institute of Technology (MIT) and was awarded a Hibbitt Independent Research Fellowship at Brown University. He also received an AME Young Investigator Award at Singapore. His research team focuses on strain engineering in 2D materials for the creation of mechanically-stable structures that can sustain large deformations and still preserve the intrinsic functionalities of 2D materials. Based on these insights, his team aims to develop stretchable 2D-material electronics for wearable technologies and multifunctional robotic materials for smart soft robots.
Haitao Yang received his bachelor's and master's degrees in Materials Science and Engineering from Zhengzhou University. Now he is a PhD candidate under the supervision of Prof. Po-Yen Chen in the National University of Singapore. His research interest focuses on developing multifunctional backbone materials for soft robotics.
Lin Jing received his PhD in Materials Science and Engineering from Nanyang Technological University, Singapore, in 2019. He is currently a research fellow under Prof. Po-Yen Chen in the Department of Chemical and Biomolecular Engineering at the National University of Singapore. His research interests lie in the topographical engineering of 2D materials and their applications in soft electromechanical and energy harvesting devices.
Kerui Li is a postdoctoral research fellow at the National University of Singapore under the supervision of Prof. Po-Yen Chen. He received his PhD in Material Science and Engineering from Donghua University, Shanghai, in 2017. Currently, he is focusing on light modulation/conversion from solar light to infrared radiation for smart clothing and soft robotics.
ISSN:2051-6347
2051-6355
DOI:10.1039/c9mh01139k