An Insight into Skeletal Networks Analysis for Smart Hydrogels

Sun, Hua; He, Yan; Wang, Zonghua; Liang, Qionglin

doi:10.1002/adfm.202108489

Cited by 13 publications

(9 citation statements)

References 263 publications

(382 reference statements)

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“…Some researches about double networks were consistent with it. [38][39][40] The following rheological measurement was performed for getting insight into the hydrogel thixotropy (Figure 1c). The storage modulus (G′) indicated the quantity of stored energy in the system, it would characterize the solid-liked property of the hydrogel; the loss modulus (G″) presented the quantity of dissipated energy in the network, it would characterize the liquidliked property of the hydrogel.…”

Section: Characterizations Of Materialsmentioning

confidence: 99%

Mussel Inspired Trigger‐Detachable Adhesive Hydrogel

Wang

Gao

Zhang

et al. 2022

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Adhesion to many kinds of surfaces, including biological tissues, is important in many fields but has been proved to be extremely challenging. Furthermore, peeling from strong adhesion is needed in many conditions, but is sometimes painful. Herein, a mussel inspired hydrogel is developed to achieve both strong adhesion and trigger‐detachment. The former is actualized by electrostatic interactions, covalent bonds, and physical interpenetration, while the latter is triggered, on‐demand, through combining a thixotropic supramolecular network and polymer double network. The results of the experiments show that the hydrogel can adhere to various material surfaces and tissues. Moreover, triggered by shear force, non‐covalent interactions of the supramolecular network are destroyed. This adhesion can be peeled easily. The possible mechanism involved is discussed and proved. This work will bring new insight into electronic engineering and tissue repair like skin care for premature infants and burn victims.

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Section: Characterizations Of Materialsmentioning

confidence: 99%

Mussel Inspired Trigger‐Detachable Adhesive Hydrogel

Wang

Gao

Zhang

et al. 2022

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“…Gels are flexible and soft materials consisting of three-dimensional (3D) crosslinked polymer networks (solid content) and numerous internal open pores filled with either solvents (liquid content, e.g., hydrogels [30][31][32] and ionogels [33][34][35] ) or air (gas content, e.g., aerogels [36][37][38] ) [39][40][41] . Due to the framework of strong bonding between polymer chains and the redundant space of internal open pores for deformation, hydrogels and ionogels exhibit an intrinsic nature of superior flexibility and stretchability.…”

Section: Gelsmentioning

confidence: 99%

“…Copyright 2022, American Chemical Society)). Six primary application directions, namely, living things, healthcare, prosthesis, human-machine interactions, electronic skin, and tissue engineering, are also illustrated (reproduced with permission [39] .…”

Section: Direct Polymerization Of Polymerizable Ilsmentioning

confidence: 99%

Recent advances in flexible and soft gel-based pressure sensors

Sun¹,

Wang²,

Jiang³

et al. 2022

Soft Sci

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Gels, as typical flexible and soft materials, possess the intrinsic merits of transparent bionic structures, superior mechanical properties and excellent elasticity and viscosity. Recently, gel-based materials have attracted significant attention as a result of their broad and promising applications in biomedical, energy storage, light emission, actuator, military and aerospace devices, especially the intelligent sensing for human-related applications. Among the various flexible and soft pressure sensors, gel-based ones have been gradually studied as an emerging hot research topic. This review focuses on the latest findings in the rapidly developing field of gel-based pressure sensors. Firstly, the classification and properties of the three types of gels and their corresponding fabrication methods are introduced. Secondly, the four basic working principles of pressure sensors are summarized with a comparison of their advantages and disadvantages, followed by an introduction to the construction of pressure sensors based on gel structures. Thirdly, the latest representative research on the three types of gel-based materials towards various wearable sensing applications, including electronic skin, human motion capture, healthcare and rehabilitation, physiological activity monitoring and human-machine interactions, is comprehensively reviewed. Finally, a summary of the remaining challenges and an outline of the development trend for this field are presented.

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“…With the rapid development of intelligence science, self-healing, tough, and stretchable materials have become highly desirable and have been attracting increasing attention for their promising application in stretchable sensors, health monitors, surface protection coatings, and so on. − Recently, great progresses have been achieved in developing self-healing hydrogels based on dynamic noncovalent interactions (hydrogen bonds, electrostatic interactions, metal coordination bonds, supramolecular interactions, and hydrophobic interactions), motivating various scientific and engineering innovations in the field of flexible devices. − However, the practical long-term application of synthetic hydrogels is susceptible due to their internal structural defects and fatigue fracture, even though their toughness could be improved by introducing multiple interactions. − On the one hand, lots of water molecules in the hydrogels can disturb the reconnection of dynamic bonds, impeding their further self-healing behavior . On the other hand, it is difficult to simultaneously enhance the mechanical strength and optimize the healing efficiency because these characteristics are contradictory. , Except for the above-mentioned two defects, endowing self-healing materials with photoluminescent (PL) property can promote and extend their applications under more complex working conditions, such as biosensors and optical switch. − …”

Section: Introductionmentioning

confidence: 99%

Double-Network Luminescent Films Constructed Using Sulfur Quantum Dots and Lanthanide Complexes

Zhang

Liang

Qin

et al. 2022

ACS Appl. Mater. Interfaces

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Although UV light-switchable luminescent films are of importance for application in soft optical devices and anticounterfeiting labels, there are still challenges in developing such films integrated with outstanding luminescent property, high self-healing efficiency, and simultaneously excellent mechanical strength. Herein, double-network (DN) luminescent films are designed and constructed via an intermolecular hydrogen bond crosslinking strategy of poly(ethylene glycol) (PEG) in sulfur quantum dots (S-QDs) and polyurethane (PU), where S-QDs (“stone” one) play dual roles of acting both as a soft segment to crosslink another segment PU (“bird” one) and also as the origin of a luminescence center (“bird” two) in films. In addition, lanthanide(III) complexes (LnCs, LnEu3+, Tb3+) are employed as another emission source to embed in the films and switch the emission colors of DN films from the multicolor (red–yellow–green) of LnCs to the blue color of S-QDs by changing the ultraviolet excitation wavelength from 254 to 365 nm. It is worth noting that the crosslinking network strategy can effectively prevent S-QDs and LnCs from aggregating or leaking and enable both luminescence centers to homogeneously distribute, resulting in luminescent DN films possessing extraordinary UV light-switchable luminescence, improved mechanical property, and excellent self-healing ability. This work presents a viable method for the design and fabrication of luminescent films with multifunctional applications in flexible robotics, wearable devices, and dual-luminescent anticounterfeiting materials.

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An Insight into Skeletal Networks Analysis for Smart Hydrogels

Cited by 13 publications

References 263 publications

Mussel Inspired Trigger‐Detachable Adhesive Hydrogel

Mussel Inspired Trigger‐Detachable Adhesive Hydrogel

Recent advances in flexible and soft gel-based pressure sensors

Double-Network Luminescent Films Constructed Using Sulfur Quantum Dots and Lanthanide Complexes

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