The combination of energy storage, electrochromic function, and physical flexibility is crucial for the development of all-solid-state flexible devices. Present work
Abstract During the past decade, flexible/stretchable energy storage devices have garnered increasing attention, with the successful development of wearable electronics.
By using liquid metal electrodes and selectively doped self-healing materials, the authors make devices with high performance, modular assembly, and application potential in
Flexible self-healing super capacitor was reported by polymerization of aniline with a physically self-healing polyvinyl alcohol/phytic acid hydrogel film. The self-repairing
Congratulations to Haili Qian and Tan Zhang et al for fabrication of anisotropic and self-healing hydrogels with impressive multi-responsive actuating capability (Nat.
This all-in-one system demonstrates a novel fabricated process and practical application of highly flexible supercapacitors to self-power integrated sensors in advanced wearable electronics and smart
They also possess features such as flexibility, self-healing, biocompatibility, self-charging, and integrability with other devices. We summarize the material design for self-charging AZBs, the device
As the demand for flexible wearable electronic devices increases, the development of light, thin and flexible high-performance energy-storage devices to power them
Flexible energy storage devices are susceptible to damage, which might result in safety issues. In this paper, a self-healing flexible P(AAPBA-co-P4-A
The self-healing double-layer hydrogel was investigated as a semicell for flexible energy storage. GCD curves were recorded (Figure 8 D) and showed symmetric triangular shapes, with a relatively short charge/discharge time,
In this review the intriguing self-healing polymers and fascinating mechanism of self-healable energy harvesting devices such as triboelectric nanogenerators (TENG) and storage devices like
This work provides new idea for the synthesis of highly conductive, self-healing and flexible hydrogel electrolyte to promote the development of all-in-one supercapacitor with
We focus on the repair mechanisms and performances of energy storage devices prepared from self-healing materials with a focus on electrodes and electrolytes. Since
This article summarizes recent advances in self-healing materials developed for energy harvesting and storage devices (e.g., nanogenerators, solar cells, supercapacitors, and lithium-ion batteries)
Nanomaterial-based self-healing electrodes have demonstrated significant potential in sensing and energy storage applications due to their ability to withstand electrical breakdowns at high electric
The introduction of self-healing mechanism into flexible energy storage devices is expected to solve the problems of mechanical and electrochemical performance degradation caused by mechanical deformation. Applications
Simultaneously, self-healing capacity, inspired by biological organs, has been identified to be a viable solution for addressing these issues by restoring mechanical and
Inspired by the healing phenomenon of nature, endowing energy storage devices with self-healing capability has become a promising strategy to efectively improve the durability and functionality
Self-Healing All-in-One Energy Storage for Flexible Self-Powering Ammonia Smartsensors Hongting Ma, Fengjuan Lv, Liuxue Shen, Kaizhou Yang, Yu Jiang, Junlin Ma, Xiaodong Geng,
In this review, we have highlighted recent progress in various types of self-healing electrolytes (solid-state, gel-state and composite electrolytes) application in flexible/stretchable
This self-healing hydrogel electrolyte with excellent stretchability and high ionic conductivity is expected to pave the way for the development of high-performance flexible energy storage and wearable
Because of the great breakthroughs of self-healing materials in the past decade, endowing devices with self-healing ability has emerged as a particularly promising route to effectively enhance the device
A variety of active materials and fabrication strategies of flexible energy storage devices have been intensively studied in recent years, especially for integrated self-powered systems and biosensing. A series of materials and
Applications of diferent healing mechanisms and advanced characterization techniques in energy storage devices are summarized. The key challenges of self-healing in the field of flexible
Herein, this review systematically summarizes the latest progress in intrinsic self-healing chemistry for energy storage devices. Firstly, the main intrinsic self-healing mechanism is introduced.
<p indent="0mm">Flexible electronics have attracted a broad attention according to their desirable mechanical deformation capabilities, such as bend, fold and stretch. The flexible
The composition and categorization of hydrogels (natural and synthesized) were explored and discussed. Moreover, this research examines the mechanical properties and self
Self-healing in AZBs endows battery with enhanced durability and extended lifespan, leading to more reliable and longer-lasting energy storage solutions. Self-healing AZBs can achieve self-repair by
Moreover, diverse properties such as self-healing ability, ultra-stretchability, electrochromism, and extreme-temperature resistance can be achieved by modifying the chemical structures, opening the door to the development of
Simultaneously, inspired by biological organs, self-healing capability is found to be a promising approach to address these issues by restoring the mechanical and electrochemical
Self-healing polymer materials have been a research hotspot in the field of smart materials since their invention. They have self-diagnostic functions and are capable of self-healing small cracks. By
Here, the state-of-the-art advances of the hydrogel materials for flexible energy storage devices including supercapacitors and rechargeable batteries are reviewed. In addition, devices with various
Simultaneously, inspired by biological organs, self-healing capability is found to be a promising approach to address these issues by restoring the mechanical and electrochemical
Innovative self-healing, flexible batteries provide enhanced safety, affordability, and performance for wearables, as detailed in a paper published by Nano Research Energy.
The introduction of self-healing mechanism into flexible energy storage devices is expected to solve the problems of mechanical and electrochemical performance degradation caused by mechanical deformation. Applications of different healing mechanisms and advanced characterization techniques in energy storage devices are summarized.
This article summarizes recent advances in self-healing materials developed for energy harvesting and storage devices (e.g., nanogenerators, solar cells, supercapacitors, and lithium-ion batteries) over the past decade.
Inspired by the healing phenomenon of nature, endowing energy storage devices with self-healing capability has become a promising strategy to effectively improve the durability and functionality of devices. Herein, this review systematically summarizes the latest progress in intrinsic self-healing chemistry for energy storage devices.
Thus, the introduction of self-healing capabilities will significantly enlarge the application field for flexible/stretchable energy storage devices, even extending the service life of both flexible/stretchable devices and traditional rigid batteries or supercapacitors, thereby reducing consumer electronic waste , , , , .
The self-healing ability can remarkably enhance the reliability and extend the lifetime of these devices. However, the self-healing of these devices is realized by the healing of either electrodes or electrolyte. Therefore, it is still an unmet challenge to generate omni-healable energy storage devices, while maintaining high power/energy density.
In general, conventional energy storage devices consist of a positive/negative electrode, separator, and package materials. The primary challenge in obtaining a flexible/stretchable device is resolving the issue of electrodes flexibility due to the intrinsic flexible feature for separator and package materials.
