Bioinspired Self‐healing Soft Electronics

Miao, Qi; Yang, Ruiqi; Wang, Zhe; Liu, Yanting; Zhang, Qichong; He, Bing; Li, Kaiwei; Yang, Qing; Wei, Lei; Pan, Caofeng; Chen, Mengxiao

doi:10.1002/adfm.202214479

Cited by 53 publications

(29 citation statements)

References 139 publications

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“…For example, a flower-shaped hydrogel is formed by ANF-Fe 3 O 4 -PVA petals and an ANF-PVA core, potentially serving as a reversible robotic hand for grasping objects (Figure 5f). Compared with other magnetic hydrogels based on self-healing strategies utilizing precursor loading, metal-coordination, hydrogen bonds, 46−48 etc., which are limited by sophisticated chemical processes and insufficient mechanical performance, 46,49 our methods exhibit a high healing efficiency, mechanical strength, and manufacturability that does not require complex chemical modifications. The chemical stability of our hydrogels further limits hazardous waste production during polymer reconfiguration and shape morphing via photothermal effects, mechanical forces, and magnetic fields, ensuring a high degree of safety.…”

Section: Resultsmentioning

confidence: 99%

High-Strength Magnetic Hydrogels with Photoweldability Made by Stepwise Assembly of Magnetic-Nanoparticle-Integrated Aramid Nanofiber Composites

Wang

Zhu

et al. 2023

ACS Nano

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Hydrogels capable of transforming in response to a magnetic field hold great promise for applications in soft actuators and biomedical robots. However, achieving high mechanical strength and good manufacturability in magnetic hydrogels remains challenging. Here, inspired by natural load-bearing soft tissues, a class of composite magnetic hydrogels is developed with tissue-mimetic mechanical properties and photothermal welding/healing capability. In these hydrogels, a hybrid network involving aramid nanofibers, Fe3O4 nanoparticles, and poly(vinyl alcohol) is accomplished by a stepwise assembly of the functional components. The engineered interactions between nanoscale constituents enable facile materials processing and confer a combination of excellent mechanical properties, magnetism, water content, and porosity. Furthermore, the photothermal property of Fe3O4 nanoparticles organized around the nanofiber network allows near-infrared welding of the hydrogels, providing a versatile means to fabricate heterogeneous structures with custom designs. Complex modes of magnetic actuation are made possible with the manufactured heterogeneous hydrogel structures, suggesting opportunities for further applications in implantable soft robots, drug delivery systems, human–machine interactions, and other technologies.

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Section: Resultsmentioning

confidence: 99%

High-Strength Magnetic Hydrogels with Photoweldability Made by Stepwise Assembly of Magnetic-Nanoparticle-Integrated Aramid Nanofiber Composites

Wang

Zhu

et al. 2023

ACS Nano

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“…Mastering nature, the creatures of the natural world have taught us much. , The lotus leaf, with its “untouched by mud” feature; the shark, with its sea-swimming abilities; and the human finger, with its ultrasensitive properties, all have their unique strengths. In this work, a drag reduction and antifouling integrated piezoresistive sensor was prepared using a sandwich structure that combines three elements.…”

Section: Resultsmentioning

confidence: 99%

Pressure-Activatable Liquid Metal Composites Flexible Sensor with Antifouling and Drag Reduction Functional Surface

Ma,

Lu,

et al. 2023

ACS Appl. Mater. Interfaces

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Flexible sensors produced through three-dimensional (3D) printing have exhibited promising results in the context of underwater sensing detection (for applications in navigational vehicles and human activities). However, underwater vehicles and activities such as swimming and diving are highly susceptible to drag, which can cause negative impacts such as reduced speed and increased energy consumption. Additionally, microbial adhesion can shorten the service life of these vehicles. However, natural organisms are able to circumvent such problems, with shark skin offering excellent barrier properties and ruffled papillae providing effective protection against fouling. Here, we show that a sandwich system consisting of a spraying layer, conductive elastomer composite, and encapsulation layer can be printed for multifunctional integrated underwater sensors. The modulated viscoelastic properties of liquid metal form the foundation for printing features, while its pressure-activated properties offer the potential for switchable sensors. An integrated drag reduction and antifouling layer were created by combining the shark skin surface shield scale structure with the lotus leaf surface papillae structure. A 3D-printed flexible sensor was designed using our approach to monitor attitude changes and strain in underwater environments, showcasing its capabilities. Our printed sensors can reduce biological attachment density by more than 50% and reduce underwater drag by 8.6−10.3%.

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“…This would enable reliable and robust operation of the device under humid conditions and deformations. [ 102 ] However, it is worth noting that there is currently limited research on semiconductive materials with water‐insensitive self‐healing ability due to synthesis challenges. Therefore, this section primarily focuses on the research progress and potential applications of water‐insensitive self‐healing materials with dielectric, electronically, and ionically conductive functions.…”

Section: Water‐insensitive Self‐healing Materials For Soft Electronicsmentioning

confidence: 99%

“…The fact that most polymers are dielectric materials explains why research on water‐insensitive self‐healing dielectric materials has outpaced their applications in soft electronics. [ 102 ] Consequently, a direct application is to use these materials as an encapsulation layer. For example, Guo's team used silicone rubber as the primary component, combined with multiple‐strength hydrogen bonds and reversible disulfide bonds, to design a highly stretchable (14 000%) and effectively water‐insensitive self‐healing dielectric polymer.…”

Section: Water‐insensitive Self‐healing Materials For Soft Electronicsmentioning

confidence: 99%

Water‐Insensitive Self‐Healing Materials: From Network Structure Design to Advanced Soft Electronics

Yao,

Liu,

Jia

et al. 2023

Adv Funct Materials

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Polymeric materials capable of spontaneously healing physical damages and restoring various functions have been attracting growing interest. Among these, the category of water‐insensitive self‐healing materials emerges as a promising research focus due to their reliable self‐healing and stable mechanical properties in high‐humidity environments and even underwater. In this review, an update on the significant advancements in the design of water‐insensitive self‐healing polymers is presented, which are based on various unique chains. Their advantages and limitations are discussed. Additionally, a series of typical dynamic interactions that are used to enable autonomous self‐healing in underwater environments is highlighted. Moving beyond these fundamental designs, the diverse opportunities to leverage recent synthetic advancements in water‐insensitive self‐healing materials for the progression of soft electronic applications are systematically discussed. Ultimately, the significant challenges and remaining opportunities to present a comprehensive view of the future development of water‐insensitive self‐healing materials are highlighted. This review aims to stimulate further innovation in this burgeoning and emerging field of intrinsic healable materials, interfacing with dynamic chemistry and soft electronics.

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Bioinspired Self‐healing Soft Electronics

Cited by 53 publications

References 139 publications

High-Strength Magnetic Hydrogels with Photoweldability Made by Stepwise Assembly of Magnetic-Nanoparticle-Integrated Aramid Nanofiber Composites

High-Strength Magnetic Hydrogels with Photoweldability Made by Stepwise Assembly of Magnetic-Nanoparticle-Integrated Aramid Nanofiber Composites

Pressure-Activatable Liquid Metal Composites Flexible Sensor with Antifouling and Drag Reduction Functional Surface

Water‐Insensitive Self‐Healing Materials: From Network Structure Design to Advanced Soft Electronics

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