A Transparent, Self‐Healing, Highly Stretchable Ionic Conductor

Cao, Yue; Morrissey, Timothy G.; Acome, Eric; Allec, Sarah I.; Wong, Bryan M.; Keplinger, Christoph; Wang, Chao

doi:10.1002/adma.201605099

Cited by 469 publications

(393 citation statements)

References 73 publications

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“…Based on this idea, the use of ILs/PILs was demonstrated in many different polymer systems, such as: block copolymer/IL-based functional soft materials presenting spontaneous repair damage by light illumination, driven by a reversible gel-sol-gel transition cycle with a reversible association/fragmentation of the polymer network [151]; IL-modified epoxy resin thermoset with self-healing ability for surface abrasion damage, where the viscoelastic recovery and healing ability of the damaged surface increases with increasing IL content (up to~12 wt %) [152]; polymer/IL-based transparent, self-healing, highly stretchable ionic conductor, used to electrically activate transparent artificial muscles, that autonomously heals using ion-dipole interactions as the dynamic motif [153]; ionically cross-linked poly(acrylic acid) (PAA) and poly-(triethyl(4-vinylbenzyl)phosphonium chloride) networks presenting a salinity dependent swelling behavior, allowing them to self-heal in low and physiologically relevant salt concentrations for biomedical area [154]; or converting bromobutyl rubber into ionic imidazolium bromide reversible ionic associates, presenting physical cross-linking ability, which facilitates the healing processes by temperature-or stress-induced rearrangements, thereby enabling a fully cut sample to retain its original properties after the self-healing process [155]; just to mention a few.…”

Section: Il-based Self-healing Materialsmentioning

confidence: 99%

Recent Applications of Ionic Liquids in the Sol-Gel Process for Polymer–Silica Nanocomposites with Ionic Interfaces

Donato

Matějka

Mauler

et al. 2017

Colloids and Interfaces

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Abstract:Understanding the organic-inorganic interphases of hybrid materials allows structure and properties control for obtaining new advanced materials. Lately, the use of ionic liquids (ILs) and poly(ionic liquids) (PILs) allowed structure control from the first sol-gel reaction steps due to their anisotropy and multiple bonding capacity. They also act as multifunctional compatibilizing agents that affect the interfacial interactions in a molecular structure-dependent manner. Thus, this review will explore the concepts and latest efforts to control silica morphology using processes such as the sol-gel, both in situ and ex situ of polymer matrices, pre-polymers or polymer precursors. It discusses how to control the polymer-filler interphase bonding, highlighting the last achievements in the interphase ionicity control and, consequently, how these affect the final nanocomposites providing materials with barrier, shape-memory and self-healing properties.

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Section: Il-based Self-healing Materialsmentioning

confidence: 99%

Recent Applications of Ionic Liquids in the Sol-Gel Process for Polymer–Silica Nanocomposites with Ionic Interfaces

Donato

Matějka

Mauler

et al. 2017

Colloids and Interfaces

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“…[231,232] Cao et al reported highly self-healing STIC using ion-dipole interactions. [43] The ionic conductor composed of poly(vinylidene fluoride-co-hexafluoropropylene) (PVDF-co-HFP) as polymer matrix and 1-ethyl-3-methyl imidazolium tetrafluoroborate (EMIOTf) as the ionic liquid shows a transmittance of 92% and can sustain a stretchability of 5000% while maintaining a high ionic conductivity of 10 −4 S cm −1 (Figure 19a,b). The presence of the reversible ion-dipole interactions impart self-healing properties to the STIC.…”

Section: Challenges and Outlookmentioning

confidence: 99%

“…Hydrogel [141] Polyacrylamide, LiCl 90 800% -Ionic cable, axion Hydrogel [42] Polyacrylamide, LiCl 98 1000% -Touch panel Ionogel [43] PVDF-co-HFP 92 5000% 10 −4 S cm…”

Section: Hydrogelsmentioning

confidence: 99%

“…Self-healing property of STIC is another advantage of soft energy devices. For example, polar polymer networks cross-linked with high ionic strength salt have been demonstrated as stretchable/ transparent/self-healing ionic conductors by using the dynamic bond formed by ion-dipole interactions [43] or hydrogen bonding interactions. [44,45] This entirely new, out-of-the-box approach to using STIC in electronic devices has gained considerable attention in the last two years, despite its nascent stage of development.…”

Section: Introductionmentioning

confidence: 99%

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Deformable and Transparent Ionic and Electronic Conductors for Soft Energy Devices

Park

Parida

Lee

2017

Advanced Energy Materials

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The recent boom in deformable or stretchable electronics, flexible transparent displays/screens, and their integration into the human body has facilitated the development of multifunctional energy devices that are stretchable, transparent, wearable, and/or biocompatible while meeting the energy or power requirements. The development of soft energy systems begins with the preparation of relevant conductors and the design of innovative device configurations. In this study, recent advances and trends in stretchable and transparent electronic and ionic conductors are reviewed coupled with the growing efforts to use them for soft energy storage and conversion systems. Stretchable transparent ionic conductors present possibilities for use as current collectors and electrolytes in soft electronic/energy devices, providing novel insight into biofriendly systems for an effective human–machine interaction. Moreover, representative examples that demonstrate soft energy devices based on stretchable transparent ionic/electronic conductors are discussed in detail. Furthermore, the challenges and perspectives of developing novel stretchable transparent conductors and device configurations with tailored features are also considered.

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“…Since multifunctional materials that bridge functional partitions drive innovation in the soft robotics field, it is worth pointing out how the self-healing materials discussed in the previous sections could continue to break down functional barriers. Recently, Cao et al (2017b) demonstrated the use of high-resistive, ionic, self-healing hydrogels as DEA electrodes, showing how work toward improving self-healing ionic hydrogels is also improving damage resilience in soft robotic actuation. Likewise, DEAs have also been used as sensory components in soft electronics (Iskandarani and Karimi, 2012;Xu et al, 2016), so progress made toward fault-tolerant and self-healing DEAs can also be applied to soft sensors and electronics.…”

Section: Future Prospects and Challengesmentioning

confidence: 99%

Self-Healing and Damage Resilience for Soft Robotics: A Review

Bilodeau

Kramer

2017

Front. Robot. AI

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Advances in soft robotics will be crucial to the next generation of robot-human interfaces. Soft material systems embed safety at the material level, providing additional safeguards that will expedite their placement alongside humans and other biological systems. However, in order to function in unpredictable, uncontrolled environments alongside biological systems, soft robotic systems should be as robust in their ability to recover from damage as their biological counterparts. There exists a great deal of work on self-healing materials, particularly polymeric and elastomeric materials that can self-heal through a wide variety of tools and techniques. Fortunately, most emerging soft robotic systems are constructed from polymeric or elastomeric materials, so this work can be of immediate benefit to the soft robotics community. Though the field of soft robotics is still nascent as a whole, self-healing and damage resilient systems are beginning to be incorporated into three key support pillars that are enabling the future of soft robotics: actuators, structures, and sensors. This article reviews the state-of-the-art in damage resilience and self-healing materials and devices as applied to these three pillars. This review also discusses future applications for soft robots that incorporate self-healing capabilities.

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A Transparent, Self‐Healing, Highly Stretchable Ionic Conductor

Cited by 469 publications

References 73 publications

Recent Applications of Ionic Liquids in the Sol-Gel Process for Polymer–Silica Nanocomposites with Ionic Interfaces

Recent Applications of Ionic Liquids in the Sol-Gel Process for Polymer–Silica Nanocomposites with Ionic Interfaces

Deformable and Transparent Ionic and Electronic Conductors for Soft Energy Devices

Self-Healing and Damage Resilience for Soft Robotics: A Review

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