This work presents a quasi-solid-state electrolyte with a dual thermal insurance mechanism based on the unique structural, designed for the
Recent advances of hydrogel electrolytes in flexible energy storage devices. Journal of Materials Chemistry A: Materials for Energy and Sustainability, 2021, 9 (4):
Introduction With the increasing demand for wearable electronic devices, there is a growing need for flexible and portable power sources. 1–5
This work presents a quasi-solid-state electrolyte with a dual thermal insurance mechanism based on the unique structural, designed for the long-term safe operation of
As a proof of concept, we show a rationally designed quasi-solid-state halide-ion-conducting gel polymer electrolyte (HGPE) which can enhance the reversible capacity and
To keep pace with higher-quality demand in modern life, flexible, wearable, and multifunctional electronic devices are now a prominent focus in
All the above performances make it very attractive for use as an electrolyte and a separator for the quasi-solid-state Zn-based energy storage devices including Zn metal
The thermal effect crisis poses a significant challenge to large‐scale application of energy storage devices. Hydrogel electrolytes are regarded as promising substrates for these applications due
标题 Quasi-Solid-State Electrochromic Energy Storage Devices with Long-Term Stability 具有长期稳定性的准固态电致变色储能器件 相关领域 电致变色 期限(时间) 固态 储
This work proposes a robust bilayer interphase between the gel electrolyte and copper current collector that combines an upper mass transfer
Lithium metal solid-state batteries are promising as rechargeable energy storage devices due to their non-combustible nature, resistance to high temperatures, and non
The currently on-going surge in portable and wearable electronics and devices has caused an ever-increasing rise in the requirement for highly compact and yet flexible energy storage
However, QSSE research remains in its infancy, with several critical challenges yet to be addressed. Finally, this review provides a comprehensive analysis of QSSEs''
Herein, in a timely response to this exciting development, we look into the recent advances in quasi-solid-state fiber-shaped aqueous ESDs, by providing a
PB/Zn EESDs stand out as a system with tremendous potential and promising applications, enabling simultaneous energy conservation and storage. Herein, we present a PB/Zn quasi
Molten salts are a unique type of electrolyte enabling high-temperature electrochemical energy storage (EES) with unmatched reversible electrode kinetics and high
In the area of electrochemical energy storage technology, quasi-solid-state electrolytes (QSSEs) are recognized as emerging electrolytic materials. With improved packing
Electrochromic energy storage devices (EESDs) offer the unique capability to monitor real-time energy storage levels while simultaneously recovering energy to reduce the power
This rational electrolyte design strategy and remarkable electrochemical performance pave the way for the next generation of energy storage devices.
In these applications, (semi-) solid-state electrolytes with strong mechanical properties and high safety levels have been used to resolve the safety hazards caused by
To this context, mechanically flexible quasi-solid-state aqueous Zn-based batteries have been regarded as a class of promising energy storage devices for these
Herein, we decouple the dual functions of electrochromism and energy storage in conventional cathodes of ECBs by introducing a polyaniline/triiodide composite cathode that
As a proof of concept, we show a rationally designed quasi-solid-state halide-ion-conducting gel polymer electrolyte (HGPE) which can
Research has progressively transitioned from liquid to solid-state electrolytes, primarily to improve safety and stability. Quasi-solid-state electrolytes (QSSEs) integrate the
Sodium-ion (Na-ion) hybrid capacitors as a novel electrochemical energy storage device have triggered considerable attention in recent years. However, the
Abstract:An Ion-Channel-Reconstructed Water/Organic Amphiphilic Quasi-Solid-State Electrolyte for High-Voltage Energy Storage Devices
PB/Zn EESDs stand out as a system with tremendous potential and promising applications, enabling simultaneous energy conservation and storage. Herein, we present a
They also allow the assembly of stretchable and bendable supercapacitors. Comparing solid-state to quasi-solid-states, the last provides the most significant energy and
Herein, in a timely response to this exciting development, we look into the recent advances in quasi-solid-state fiber-shaped aqueous ESDs, by providing a comprehensive and critical
The thermal effect crisis poses a significant challenge to large-scale application of energy storage devices. Hydrogel electrolytes are
Sodium-ion (Na-ion) hybrid capacitors as a novel electrochemical energy storage device have triggered considerable attention in recent years. However, the sluggish kinetics at
PB/Zn EESDs stand out as a system with tremendous potential and promising applications, enabling simultaneous energy conservation and storage. Herein, we present a PB/Zn quasi-solid-state EESD, which incorporates an in situ photopolymerized Zn 2+ –K + hybrid quasi-solid-state electrolyte.
Herein, in a timely response to this exciting development, we look into the recent advances in quasi-solid-state fiber-shaped aqueous ESDs, by providing a comprehensive and critical overview of new design principles, key progress in both materials and devices, and system integrations.
It is an urgent demand on electrolyte design, tuning these characteristics for better battery performance. Quasi-solidification is an effective strategy of electrolyte design to overcome the disadvantages of electrolyte leakage and volatilization in room-temperature batteries with liquid electrolytes.
Cite this: CCS Chem. 2025, 7, 470–483 Quasi-solid-state electrolytes (QSSEs) have garnered significant attention due to combining the dynamic properties of liquid electrolytes and the high safety of solid-state electrolytes.
We also report assembly and testing of fluoride-ion and bromide-ion cells using quasi-solid-state halide-ion-conducting gel polymer electrolyte. Lithium (Li)–ion batteries have dominated the market of portable energy storage devices in the past few decades due to their high energy density.
To address these challenges, in this study, a multifunctional composite quasi-solid-state electrolyte (CQE) was synthesized by electrospinning poly (vinylidene fluoride-hexafluoropropylene) (PVDF-HFP) fibers on both sides of an aramid nanofibers (ANFs) fibrous film for application in high-performance FSBs.
