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In Situ Grown Silver–Polymer Framework with Coordination Complexes for Functional Artificial Tissues

Self‐sensing actuators are critical to artificial robots with biomimetic proprio‐/exteroception properties of biological neuromuscular systems. Existing add‐on approaches, which physically blend heterogeneous sensor/actuator components, fall short of yielding satisfactory solutions, considering thei...

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Published in:	Advanced materials (Weinheim) 2023-06, Vol.35 (24), p.e2207916-n/a
Main Authors:	Zhang, Songlin, Deng, Yibing, Libanori, Alberto, Zhou, Yihao, Yang, Jiachen, Tat, Trinny, Yang, Lin, Sun, Wanxin, Zheng, Peng, Zhu, You‐Liang, Chen, Jun, Tan, Swee Ching
Format:	Article
Language:	English
Subjects:	Actuation Actuators Artificial tissues Biological properties Biomimetics Chemical synthesis conductive elastomers Coordination Complexes Coordination compounds Elastomers electronic skins Humans Metal Nanoparticles Nanoparticles Polymers Robots self‐sensing actuators Silver silver nanoparticles
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cited_by	cdi_FETCH-LOGICAL-c4136-82cfa9991397f60c7ebd273ef05440dc01fc4cc667c89f5e474b591139ebc97f3
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container_title	Advanced materials (Weinheim)
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creator	Zhang, Songlin Deng, Yibing Libanori, Alberto Zhou, Yihao Yang, Jiachen Tat, Trinny Yang, Lin Sun, Wanxin Zheng, Peng Zhu, You‐Liang Chen, Jun Tan, Swee Ching
description	Self‐sensing actuators are critical to artificial robots with biomimetic proprio‐/exteroception properties of biological neuromuscular systems. Existing add‐on approaches, which physically blend heterogeneous sensor/actuator components, fall short of yielding satisfactory solutions, considering their suboptimal interfaces, poor adhesion, and electronic/mechanical property mismatches. Here, a single homogeneous material platform is reported by creating a silver–polymer framework (SPF), thus realizing the seamless sensing–actuation unification. The SPF‐enabled elastomer is highly stretchable (1200%), conductive (0.076 S m−1), and strong (0.76 MPa in‐strength), where the stretchable polymer matrix synthesis and in situ silver nanoparticles reduction are accomplished simultaneously. Benefiting from the multimodal sensing capability from its architecture itself (mechanical and thermal cues), self‐sensing actuation (proprio‐deformations and external stimuli perceptions) is achieved for the SPF‐based pneumatic actuator, alongside an excellent load‐lifting attribute (up to 3700 times its own weight), substantiating its advantage of the unified sensing–actuation feature in a single homogenous material. In view of its human somatosensitive muscular systems imitative functionality, the reported SPF bodes well for use with next‐generation functional tissues, including artificial skins, human–machine interfaces, self‐sensing robots, and otherwise dynamic materials. The concept of creating a silver–polymer framework (SPF) is proposed, in which silver nanoparticles (AgNPs) are in situ grown (for sensing) with simultaneous formation of metal–ligand coordination complexes (for actuating). The seamless sensing–actuation unification at nano‐/molecular levels in a single homogenous material platform simultaneously imparts multimodal sensation and excellent load‐lifting into soft robots, thus fully mimicking sensory motions (proprio‐/exteroception) of biological organisms.
doi_str_mv	10.1002/adma.202207916
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Benefiting from the multimodal sensing capability from its architecture itself (mechanical and thermal cues), self‐sensing actuation (proprio‐deformations and external stimuli perceptions) is achieved for the SPF‐based pneumatic actuator, alongside an excellent load‐lifting attribute (up to 3700 times its own weight), substantiating its advantage of the unified sensing–actuation feature in a single homogenous material. In view of its human somatosensitive muscular systems imitative functionality, the reported SPF bodes well for use with next‐generation functional tissues, including artificial skins, human–machine interfaces, self‐sensing robots, and otherwise dynamic materials. The concept of creating a silver–polymer framework (SPF) is proposed, in which silver nanoparticles (AgNPs) are in situ grown (for sensing) with simultaneous formation of metal–ligand coordination complexes (for actuating). 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subjects	Actuation Actuators Artificial tissues Biological properties Biomimetics Chemical synthesis conductive elastomers Coordination Complexes Coordination compounds Elastomers electronic skins Humans Metal Nanoparticles Nanoparticles Polymers Robots self‐sensing actuators Silver silver nanoparticles
title	In Situ Grown Silver–Polymer Framework with Coordination Complexes for Functional Artificial Tissues
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