Versatile Agar‐Zwitterion Hybrid Hydrogels for Temperature Self‐Sensing and Electro‐Responsive Actuation

Although recent years have seen considerable interest in stimuli‐responsive hydrogels, their strict preparation conditions and narrow applicability limit their use as diverse sensors and soft robots. Herein, a versatile Agar‐Zwirrions hybrid hydrogel actuator (Agar/PSBMA) integrated with simultaneou...

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Veröffentlicht in:	Advanced functional materials 2024-05, Vol.34 (19), p.n/a
Hauptverfasser:	Yang, Jueying, Huang, Weiting, Peng, Kelin, Cheng, Zhekun, Lin, Lizhi, Yuan, Jingjing, Sun, Yi, Cho, Nam‐Joon, Chen, Yu
Format:	Artikel
Sprache:	eng
Schlagworte:	Actuation Actuators adhesion Controllability Electric fields Finite element method hybrid double‐network hydrogels Hydrogels Mechanical properties Preforming Robotics Stretchability temperature self‐sensing wide‐range electrical response Zwitterions
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creator	Yang, Jueying Huang, Weiting Peng, Kelin Cheng, Zhekun Lin, Lizhi Yuan, Jingjing Sun, Yi Cho, Nam‐Joon Chen, Yu
description	Although recent years have seen considerable interest in stimuli‐responsive hydrogels, their strict preparation conditions and narrow applicability limit their use as diverse sensors and soft robots. Herein, a versatile Agar‐Zwirrions hybrid hydrogel actuator (Agar/PSBMA) integrated with simultaneous temperature self‐sensing and wide‐range electrical response is developed. To prepare the Agar/PSBMA hydrogel, a simple and controllable preforming post‐enhancing and mechanical pressing method is used by introducing zwitterions materials into a temperature‐sensitive Agar matrix. Owing to the design, the compact multiplex complementary structure generated by this method and the materials can facilitate the improvement of flexibility, stretchability, and toughness while providing mechanical dissipation and adhesion properties. Importantly, the visible detected temperature self‐sensing ability during 10–40 °C, and quick and wide‐range bending responses of both high‐voltage and low‐voltage electric fields make it unique over other actuators. Furthermore, the electrical response behavior of the hydrogel is found to be impacted by mechanical characteristics and charge polarization based on the finite element Abaqus simulations analysis. The prepared versatile hydrogels show the potential for applications as soft robotics and controlled transportation of adhered substances while simultaneously monitoring their working temperature, which expands the response range of hydrogel actuators and broadens the scope of application. The versatile hybrid hydrogel is developed by incorporating zwitterions into a temperature‐sensitive Agar matrix via simple preforming post‐enhancing and mechanical pressing methods. This Agar/PSBMA hydrogel shows mechanical stability, temperature self‐sensing, wide‐range bending responses of high‐voltage and low‐voltage electric fields, and potential for use in soft robotics and controlled substance transport.
doi_str_mv	10.1002/adfm.202313725
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Furthermore, the electrical response behavior of the hydrogel is found to be impacted by mechanical characteristics and charge polarization based on the finite element Abaqus simulations analysis. The prepared versatile hydrogels show the potential for applications as soft robotics and controlled transportation of adhered substances while simultaneously monitoring their working temperature, which expands the response range of hydrogel actuators and broadens the scope of application. The versatile hybrid hydrogel is developed by incorporating zwitterions into a temperature‐sensitive Agar matrix via simple preforming post‐enhancing and mechanical pressing methods. 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subjects	Actuation Actuators adhesion Controllability Electric fields Finite element method hybrid double‐network hydrogels Hydrogels Mechanical properties Preforming Robotics Stretchability temperature self‐sensing wide‐range electrical response Zwitterions
title	Versatile Agar‐Zwitterion Hybrid Hydrogels for Temperature Self‐Sensing and Electro‐Responsive Actuation
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