Adaptive Ionogel Paint from Room‐Temperature Autonomous Polymerization of α‐Thioctic Acid for Stretchable and Healable Electronics

Wang, Yingjie; Sun, Shengtong; Wu, Peiyi

doi:10.1002/adfm.202101494

Cited by 135 publications

(133 citation statements)

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“…This phenomenon of energy dissipation is commonly observed in many gel systems with noncovalent interactions. [17,34,35] With an increase of tensile strain, the hysteresis area and hysteresis ratio of the loading-unloading cycles both increased (Figure S14, Supporting Information). These results indicated that more noncovalent bonds in the ionogel network were destroyed as the strain increased, which dissipated more energy and triggered more structural change.…”

Section: Mechanical Propertiesmentioning

confidence: 99%

A Transparent, Highly Stretchable, Solvent‐Resistant, Recyclable Multifunctional Ionogel with Underwater Self‐Healing and Adhesion for Reliable Strain Sensors

et al. 2021

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applications, including solid electrolytes, [7] energy storage/generation devices, [8][9][10] electroactive actuators, [11] strain sensors, [12,13] soft robotics, [14] stretchable touch panels, [15] membrane separation, [16] and so on.To further expand the applications of ionogels, different strategies have been reported to combine various other desirable properties with ionogels, including self-healing capability, [17][18][19] high mechanical strength and resilience, [20,21] resistance against water and organic solvents, [22,23] and self-adhesiveness. [12,24] The integration of different properties with the highly conductive and stable nature of ionogels is essential to meet the requirements for practical applications in complex scenarios. For example, very recently, Wu et al. reported a class of ionogels with underwater self-healing ability and underwater adhesiveness, which demonstrated intriguing applications such as underwater communication. However, these ionogels showed only moderate conductivity, strain-softening behavior, and moderate mechanical recoverability. [25] Although multifunctional hydrogels have been extensively studies in recent years, [26][27][28] to date, it is still a great challenge to design ionogels that combine high comprehensive performance and multiple functions.Herein, we report the design and characterization of a class of physically crosslinked multifunctional ionogels that are highly transparent (>92% in visible region), highly stretchable (up to 2066%), mechanically strong (breaking strength up to 0.72 MPa), highly conductive (up to 2.92 mS cm −1 at 25 °C), and is capable to self-heal at room temperature both in air and under water. Besides, this kind of ionogel shows excellent resistance against aqueous solutions and some organic solvents, strong underwater adhesion to diverse substrates, and can be feasibly recycled by dissolving in ethanol and reprocessed into arbitrary shapes. Moreover, the ionogel-based sensor shows sensitive and repeatable sensing signals for a wide range deformation in tension or compression, including stable strain sensing in diverse liquid media, which was used for the reliable and sensitive wearable strain sensor to monitor human's motions. Our study would provide a kind of multifunctional ionogels with excellent comprehensive performance for wearable devices and sensing applications.Ionogels have gained increasing attentions as a flexible conductive material. However, it remains a big challenge to integrate multiple functions into one gel that can be widely applied in various complex scenes. Herein, a kind of multifunctional ionogels with a combination of desirable properties, including transparency, high stretchability, solvent and temperature resistance, recyclability, high conductivity, underwater self-healing ability, and underwater adhesiveness is reported. The ionogels are prepared via one-step photoinitiated polymerization of 2,2,2-trifluoroethyl acrylate and acrylamide in a hydrophobic ionic liquid. The abundant noncovalent interactions includi...

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Section: Mechanical Propertiesmentioning

confidence: 99%

A Transparent, Highly Stretchable, Solvent‐Resistant, Recyclable Multifunctional Ionogel with Underwater Self‐Healing and Adhesion for Reliable Strain Sensors

et al. 2021

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“…Figure 3e shows the stretchability and durability of the recently reported hydrogel-, organohydrogel-and ionogel-based ionic conductors. [10][11][12][13][14][19][20][21][24][25][26][27][28][29][30][31]34,35,[49][50][51][52][53][54][55][56][57][58] Our VPVA 40% -IL ionic conductors are at record levels in terms of their stretchability and durability, demonstrating their considerable potential for use in flexible electronics and devices.…”

Section: Durability and Healability Of The Vpva 40% -Il Ionic Conductorsmentioning

confidence: 99%

Highly Stretchable, Elastic, Healable, and Ultra-Durable Polyvinyl Alcohol-Based Ionic Conductors Capable of Safe Disposal

Wang

et al. 2022

CCS Chem

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“…[21] Meanwhile, there has also been a growing interest to explore soft polymeric hydrogels for flexible sensors. [22][23][24][25][26][27][28][29][30][31][32] Different from elastomers, polymeric hydrogels usually have a 3D crosslinked hydrophilic network that is highly swollen by water. [5,33] Thus they are endowed with many unique advantages, including intrinsic soft wet nature, good biocompatibility, and especially tissue-like mechanical properties, which have made polymeric hydrogels promising candidates for flexible sensors.…”

mentioning

confidence: 99%

Dual‐Channel Flexible Strain Sensors Based on Mechanofluorescent and Conductive Hydrogel Laminates

Lin

Wang

et al. 2022

Advanced Optical Materials

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such as carbon nanotubes, graphene, nanowires) into soft elastomer composites. [8][9][10][11][12][13][14][15][16] Nevertheless, most of these reported flexible strain sensors could only display one single electrical signal output, which might have some practical use limitations. Especially with the development of human-machine interactive systems, there has been an increasing demand for dual-channel reporting flexible sensors, which are capable of exhibiting both strain-dependent electrical and optical changes. [17][18][19][20][21] Among various optical means, fluorescence is believed to quite promising for wearable stretchable sensing uses because of its high sensitivity, fast response and operational simplicity. The most convenient strategy is to develop the mechanofluorescent elastomer materials with strain-dependent electrical signal response. One famous example was reported by Zhang and colleagues who draw inspiration from the muscle-controlled display tactics of cephalopods to present the robust nanostructured self-healable and mechanoluminescent elastomer composites, which were capable of displaying reversible strain-dependent luminescence and resistance response to tensile strain. [21] Meanwhile, there has also been a growing interest to explore soft polymeric hydrogels for flexible sensors. [22][23][24][25][26][27][28][29][30][31][32] Different from elastomers, polymeric hydrogels usually have a 3D crosslinked hydrophilic network that is highly swollen by water. [5,33] Thus they are endowed with many unique advantages, including intrinsic soft wet nature, good biocompatibility, and especially tissue-like mechanical properties, which have made polymeric hydrogels promising candidates for flexible sensors. [34] In this context, considerable progresses have been recently achieved in soft conductive hydrogels with strain-dependent electronic signal changes. However, it still remains challenging to develop the promising dual-channel hydrogel systems with both sensitive conductivity and interactive fluorescence color changes to dynamic activities, which would show potentials to enable both electronic and visual monitoring of human motions. This is possibly because it is quite difficult to construct robust multifunctional materials with continuous and synergistic fluorescence/electronic signal responses over a wide strain range.Flexible strain sensors are of great importance in many emerging applications for human motion monitoring, implanted devices, and humanmachine interactive systems. However, the dual-channel sensing systems that enable both strain-dependent electronic and visually optical signal responses still remain underdeveloped, but such systems are of great interest for human-machine interactive uses. Here, inspired by the mechanically modulated skin color changes of squids via muscle contracting/releasing movements, a class of mechanofluorescent and conductive hydrogel laminates for visually flexible electronics is presented. The sensing laminates consist of interfacially bonded red fluorescent hyd...

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Adaptive Ionogel Paint from Room‐Temperature Autonomous Polymerization of α‐Thioctic Acid for Stretchable and Healable Electronics

Cited by 135 publications

References 58 publications

A Transparent, Highly Stretchable, Solvent‐Resistant, Recyclable Multifunctional Ionogel with Underwater Self‐Healing and Adhesion for Reliable Strain Sensors

A Transparent, Highly Stretchable, Solvent‐Resistant, Recyclable Multifunctional Ionogel with Underwater Self‐Healing and Adhesion for Reliable Strain Sensors

Highly Stretchable, Elastic, Healable, and Ultra-Durable Polyvinyl Alcohol-Based Ionic Conductors Capable of Safe Disposal

Dual‐Channel Flexible Strain Sensors Based on Mechanofluorescent and Conductive Hydrogel Laminates

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