Dynamically Crosslinked Dry Ion‐Conducting Elastomers for Soft Iontronics

Zhang, Panpan; Guo, Wenbin; Guo, Zi Hao; Ma, Yuan; Gao, Lei; Cong, Zifeng; Zhao, Xiangyu; Li, Qiao; Pu, Xiong; Wang, Zhong Lin

doi:10.1002/adma.202101396

Cited by 150 publications

(161 citation statements)

References 54 publications

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“…We attribute this stability to two aspects: the ability of the electret to preserve the electrostatic charges for longevity, and the solvents of organohydrogel electrodes are not subject to leakage or evaporation under room temperature (fig. S10) ( 33 , 38 ). In detail, the EG/water binary system, the polarity of Li + , and the encapsulation of electrode all worked together to significantly alleviate the water evaporation, contributing to the stability of organohydrogel electrode.…”

Section: Resultsmentioning

confidence: 99%

Bioinspired soft electroreceptors for artificial precontact somatosensation

et al. 2022

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Artificial haptic sensors form the basis of touch-based human-interfaced applications. However, they are unable to respond to remote events before physical contact. Some elasmobranch fishes, such as seawater sharks, use electroreception somatosensory system for remote environmental perception. Inspired by this ability, we design a soft artificial electroreceptor for sensing approaching targets. The electroreceptor, enabled by an elastomeric electret, is capable of encoding environmental precontact information into a series of voltage pulses functioning as unique precontact human interfaces. Electroceptor applications are demonstrated in a prewarning system, robotic control, game operation, and three-dimensional object recognition. These capabilities in perceiving proximal precontact events can lenrich the functionalities and applications of human-interfaced electronics.

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Section: Resultsmentioning

confidence: 99%

Bioinspired soft electroreceptors for artificial precontact somatosensation

et al. 2022

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“…Furthermore, they show a significant increase in resistance during stretching because of the generation of separation and break in the integrated conductive components [13,14]. Distinct from the electronic conductors, ionic conductors can be constructed based on intrinsically stretchable polymer networks in which current is transported by mobile ions [15][16][17]. Thus, the stretchable ionic conductors exhibit a smaller change in resistance and are more tolerant under extension [14,18].…”

Section: Introductionmentioning

confidence: 99%

Transparent, stretchable and anti-freezing hybrid double-network organohydrogels

Zhu

Song

et al. 2022

Sci. China Mater.

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Stretchable ionic conductors with high transparency and excellent resilience are highly desired for flexible electronics, but traditional ionic conductive hydrogels are easy to dry and freeze. Herein, a newly hybrid crosslinking strategy is presented for preparing a stretchable and transparent hydrogel by using sodium alginate (SA) and acrylamide based on the unique physically and covalently hybrid crosslinking mechanism, which is transformed into organohydrogel by simple solvent replacement. Due to the combination of hybrid crosslinking double network and hydrogen bond interactions introduced by the glycerin-water binary solvent, the SA-poly (acrylamide)-organohydrogel (SPOH) demonstrates excellent anti-freezing (−20°C) property, stability (>2 days), transparency, stretchability (~1600%) and high ionic conductivity (17.1 mS cm −1 ). Thus, a triboelectric nanogenerator made from SPOH (O-TENG) shows an instantaneous peak power density of 262 mW m −2 at a load resistance of 10 MΩ and efficiently harvests biomechanical energy to drive an electronic watch and light-emitting diode. Moreover, The O-TENG exhibits favorable long-term stability (2 weeks) and temperature tolerance (−20°C). In addition, the raw materials can be prepared into SPOH fibers by a simple tubular mold method, exhibiting high transparency, which can be used for laser transmission. The various abilities of the SPOH promise the application of energy harvesting and laser transmission for wearable electronics and biomedical field.

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“…More specifically, self-healing ionogels have been fabricated by loading ILs in polymer networks that are crosslinked by reversible covalent bonds or noncovalent bonds. 21,34–43 The dynamic nature of reversible covalent bonds and noncovalent bonds allows the ionogels to reform the network at the injured site after damage, restoring their original structural and functional integrity. For instance, Yue and co-workers reported the fabrication of a water-proof self-healing ionogel by polymerization of 2,2,2-trifluoroethyl acrylate and acrylamide in a hydrophobic ionic liquid.…”

Section: Introductionmentioning

confidence: 99%

“…Self-healing ionogels have demonstrated promise in applications in the fields of energy storage/generation devices, 34,36–38 and strain sensors. 21,39,40 However, most of the reported self-healing ionogels have poor mechanical strength (tensile stress < 1 MPa), which originates from the dynamic network inside the ionogels.…”

Section: Introductionmentioning

confidence: 99%