Transparent, mechanically robust, and ultrastable ionogels enabled by hydrogen bonding between elastomers and ionic liquids

Gao

Macro Chemistry & Physics

et al. 2020

Conductive smart hydrogels with several virtues such as similar characters to biological tissues, sensitive response to ambient variations, have shown their excellent talents in the field of flexible electrical sensors, biomedical devices and directional transportation. However, complex preparing approaches or the instable inner structures have not only been time‐consuming, but also broken up the performance and reliability of the smart hydrogel‐based devices. In this work, a facile one‐step method is put forward to synthesize a kind of conductive poly(N‐isopropylacrylamide) (PNIPAM) hydrogel doped by a new green solvent of deep eutectic solvent (DES) containing choline chloride (ChCl) and acrylic acid (AA). Through the copolymerization of AA and NIPAM, the mechanical strength of the DES‐doped PNIPAM hydrogels is drastically improved compared to the pure PNIPAM gels, and some doped hydrogels lost the typical phase transition temperature of PNIPAM. Moreover, due to the ionic property of DES, the hybrid hydrogels also present the thermal‐depending conductivity as well as sensitive deformation response, which can be used as a smart switch in a circuit or a sensing element with environmental response ability. The cost‐effective preparation and the attractive performance of the DES‐doped hydrogels offer a new avenue to construct multi‐functional materials.

Section: Resultsmentioning

confidence: 99%

Conductive and Tough Smart Poly(N‐isopropylacrylamide) Hydrogels Hybridized by Green Deep Eutectic Solvent

Gao

Macro Chemistry & Physics

et al. 2020

“…[ 25 ] Strategies such as fabricating conductive nanochannels and employing ILs that can form hydrogen bonds with polymer chains have been proposed to prevent the loss of ILs. [ 25,26 ] Meanwhile, the tradeoff between ionic conductivity and mechanical robustness should be addressed as well—in general, using a large amount of ILs can enhance the conductivity of gels but cause degradation of mechanical properties (e.g., strength and modulus). [ 3,22,25 ] More recently, ionotronic diodes and transistors have been demonstrated with the use of ionic conductive elastomers that are comprised entirely of polymer networks and mobile ions and contain no liquid components, such that these devices are non‐volatile without the hassles of leaking liquid materials.…”

Section: Figurementioning

confidence: 99%

“…At the molecular scale, dense arrays of hydrogen bonds form between the anions and copolymer network, with the hydrogen atoms in the P(MEA‐ co ‐IBA) chains acting as hydrogen bond donors and the electronegative atoms (such as F and N) in the TFSI anions serving as the acceptors. [ 26 ] In addition, a large number of lithium bonds formed between lithium cations and carbonyl oxygens on polymer chains are confimed by attenuated total reflectance Fourier transform infrared spectroscopy (Figure S10, Supporting Information). Lithium bonds are much stronger than hydrogen bonds.…”

Section: Figurementioning

confidence: 99%

A Mechanically Robust and Versatile Liquid‐Free Ionic Conductive Elastomer

et al. 2021

Soft ionic conductors, such as hydrogels and ionogels, have enabled stretchable and transparent ionotronics, but they suffer from key limitations inherent to the liquid components, which may leak and evaporate. Here, novel liquid‐free ionic conductive elastomers (ICE) that are copolymer networks hosting lithium cations and associated anions via lithium bonds and hydrogen bonds are demonstrated, such that they are intrinsically immune from leakage and evaporation. The ICEs show extraordinary mechanical versatility including excellent stretchability, high strength and toughness, self‐healing, quick self‐recovery, and 3D‐printability. More intriguingly, the ICEs can defeat the conflict of strength versus toughness—a compromise well recognized in mechanics and material science—and simultaneously overcome the conflict between ionic conductivity and mechanical properties, which is common for ionogels. Several liquid‐free ionotronics based on the ICE are further developed, including resistive force sensors, multifunctional ionic skins, and triboelectric nanogenerators (TENGs), which are not subject to limitations of previous gel‐based devices, such as leakage, evaporation, and weak hydrogel–elastomer interfaces. Also, the 3D printability of the ICEs is demonstrated by printing a series of structures with fine features. The findings offer promise for a variety of ionotronics requiring environmental stability and durability.

“…Ionic conductors are not confined to hydrogels and can also be formed as ionogels—ionic liquid-based gel systems—and also elastomers that include ions or ionic liquids. Ionogels are a new class of soft materials with ionic conductivity and thermal stability, and unlike most hydrogels, do not dry out in open air, offering a promising option for soft stretchable conductors [ 13 , 120 , 128 , 129 , 130 , 131 , 132 ]. Figure 5 depicts examples of transparent ionogels ( Figure 5 a,b) along with a representative demonstration of mechanical strain ( Figure 5 b).…”

Section: Materials Considerationsmentioning

confidence: 99%

“… ( a ) Schematic description of a transparent, mechanically robust, and stable ionogel enabled by hydrogen bonding. Reproduced with permission from [ 128 ]. Copyright 2020, Royal Society of Chemistry ( b ) Mechanical characterization of a 3D printed crosslinked ionogel.…”

Section: Figurementioning

confidence: 99%

Advances in Materials for Soft Stretchable Conductors and Their Behavior under Mechanical Deformation

Nguyen

Khine

2020

Polymers

Soft stretchable sensors rely on polymers that not only withstand large deformations while retaining functionality but also allow for ease of application to couple with the body to capture subtle physiological signals. They have been applied towards motion detection and healthcare monitoring and can be integrated into multifunctional sensing platforms for enhanced human machine interface. Most advances in sensor development, however, have been aimed towards active materials where nearly all approaches rely on a silicone-based substrate for mechanical stability and stretchability. While silicone use has been advantageous in academic settings, conventional silicones cannot offer self-healing capability and can suffer from manufacturing limitations. This review aims to cover recent advances made in polymer materials for soft stretchable conductors. New developments in substrate materials that are compliant and stretchable but also contain self-healing properties and self-adhesive capabilities are desirable for the mechanical improvement of stretchable electronics. We focus on materials for stretchable conductors and explore how mechanical deformation impacts their performance, summarizing active and substrate materials, sensor performance criteria, and applications.