Zinc based micro‐electrochemical energy storage devices: Present status and future perspective

Wang, Xiao; Wu, Zhong‐Shuai

doi:10.1002/eom2.12042

Cited by 36 publications

(23 citation statements)

References 138 publications

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“…In addition, TA-gel-supported microsensors integrated with stretchable supercapacitors were demonstrated for multifunctional on-skin applications. Not limited to supercapacitor and strain/UV sensing presented in this work, various polyphenol-incorporated gels based on diverse polymer networks could be further developed to accommodate wearable microbatteries, healable and recyclable electronics, , or self-powered chem/biosensing. , Furthermore, since TA is also a bioactive compound displaying antibacterial and antioxidation properties, our approach could pave a route to soft ionic conductors with integrated physical/chemical/biological functions and spatiotemporal control, , which is anticipated to drive advances in wearable monitoring, “green” ubiquitous electronics or clinical prospects in implanted devices and regenerative medicine.…”

Section: Discussionmentioning

confidence: 99%

Reversibly Stretchable Organohydrogel-Based Soft Electronics with Robust and Redox-Active Interfaces Enabled by Polyphenol-Incorporated Double Networks

Wang

Chen

Fang

et al. 2022

ACS Appl. Mater. Interfaces

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Hydrogel electrolytes as soft ionic conductors have been extensively exploited to establish skinlike and biocompatible devices. However, in many common hydrogels, there exists irreversible elongation upon prolonged stretching cycles and poor interfacial contact, which have significantly hindered their practical applications where long-term operation at large deformations is needed. Herein, multifunctional soft electronic devices with reversible stretchability and improved electrode/electrolyte interfaces are demonstrated by employing polyacrylamide-based double-network organohydrogel electrolytes soaked with a high content of tannic acid (TA) that affords multiple noncovalent interactions and redox activity. Performances of the TA-rich gels are evaluated for the first time in realizing shape-recoverable stretchable devices against repeated deformations to 500% strain, with superior gel−electrode interfaces exhibiting both intimate adhesion and boosted electrochemical capacitance of >200 mF•cm −2 . A maximal 4-fold higher capacitance can be achieved by introducing TA and ethylene glycol (EG) into hydrogels. Moreover, a soft electronic system consisting of stretchable supercapacitors and gel-based microsensors was demonstrated, in which the electronic performance of these devices can be well preserved after >1000 repeated cycles at strains of up to 200%, without obvious residual strain or electrode delamination. This could pave a route to the design of multifunctional gel networks tackling both the mechanical and interfacial issues in soft and biocompatible devices.

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Section: Discussionmentioning

confidence: 99%

Reversibly Stretchable Organohydrogel-Based Soft Electronics with Robust and Redox-Active Interfaces Enabled by Polyphenol-Incorporated Double Networks

Wang

Chen

Fang

et al. 2022

ACS Appl. Mater. Interfaces

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“…Currently, some new rechargeable metal-ion batteries including Na + , K + , Al 3+ , and Zn 2+ batteries have obtained increasing attention as the alternative energy storage systems for lithium-ion batteries. − Among them, the metallic Zn anode with its intrinsic safety, abundant reserves, high safety, and environmental friendliness has aroused intense research in rechargeable batteries. − Inspired by zinc-ion batteries (ZIBs), zinc-ion microbatteries (ZIMBs) have been reported recently and inherited their advantages . However, ZIMBs face a number of critical challenges in developing high-performance anodes and cathodes similar to ZIBs .…”

Section: Introductionmentioning

confidence: 99%

Vertical Graphene Film Enables High-Performance Quasi-Solid-State Planar Zinc-Ion Microbatteries

Zhou

Xie

et al. 2023

ACS Appl. Mater. Interfaces

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With the advantages of low cost, high safety, and environmental friendliness, quasi-solid-state zinc-ion microbatteries (ZIMBs) have received widespread attention in the field of flexible wearable devices and on-chip integratable energy storage. However, hysteresis Zn-ion transport kinetics and inhomogeneous growth of the zinc anode result in the poor capacity reversibility and cycling stability. Herein, a quasi-solid-state planar zinc-ion cell was developed by employing a vertical graphene (VG) film as an effective conductive modification layer for both the cathode and anode. The VG distinctly induces uniform Zn deposition/stripping, accelerates the charge transport, and enhances the adhesion between the active materials and current collectors. As a result, planar Zn@VG//MnO 2 @VG exhibits a high areal capacity of 159 μAh cm −2 , a remarkably high areal energy/power density of 201.5 μWh cm −2 /67.16 μW cm −2 , and a high capacity retention of 95.6% at a bending angle of 180°. The proposed facile strategy for electrode modification provides a new insight into the design of high-performance flexible and planar ZIMBs.

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“…Furthermore, although seldomly reported among various MESDs as the integrated micropower source, ZIMB is extremely competitive for healthcare and medical applications due to its advantages in good biosafety, low cost, high energy density, good cycle stability, and facile for integrations. 20,[31][32][33][34] One characteristic of resistive-type sensors is their significant current variations under working with simple circuit designs and connections with the MESDs. However, to the electrochemical sensors, signals of current variations and others are unusually very weak, making their effective detections a difficult task by using the common circuit designs.…”

Section: Introductionmentioning

confidence: 99%

“…These progresses realize the successful integration of sensors and MESDs; however, it is noted that the integrable sensors based on these reports mainly belong to resistive‐type sensors, which have limitations in practical situations. Furthermore, although seldomly reported among various MESDs as the integrated micropower source, ZIMB is extremely competitive for healthcare and medical applications due to its advantages in good biosafety, low cost, high energy density, good cycle stability, and facile for integrations 20,31–34 …”

Section: Introductionmentioning

confidence: 99%

Integration of all‐printed zinc ion microbattery and glucose sensor toward onsite quick detections

Jiang

Wen

Deng

et al. 2022

SusMat

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Rational design of microsystems and efficient integration of various functional modules that can directly realize the aimed functions are very attractive for portable and onsite practical applications, which is also significant in developing miniaturized and intelligent electronics and equipment. Unlike the conventional electrochemical glucose sensors that always need auxiliary complex systems for power supply, signal processing, and feedbacks, we design an all‐printed glucose sensor integrated with a zinc ion microbattery (ZIMB) as a micropower source for portable and onsite quick glucose detections. The integrated glucose sensor (GS) and ZIMB (iGS‐ZIMB) system possesses a high areal energy density of 247.3 μWh/cm2 and power density of 1193 μW/cm2 and exhibits high sensitivity up to 464.2 μA/mM/cm2, wide linear range of 0.5–6.0 mM, and good reproducibility in glucose detections. Through a simple amplification circuit design, the glucose concentration signals could be displayed within a short response time of 1.6 s without the need of external auxiliary equipment. Such iGS‐ZIMB microsystem has prominent advantages in efficiency and cost and is promising for onsite medical and healthcare applications.

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Zinc based micro‐electrochemical energy storage devices: Present status and future perspective

Cited by 36 publications

References 138 publications

Reversibly Stretchable Organohydrogel-Based Soft Electronics with Robust and Redox-Active Interfaces Enabled by Polyphenol-Incorporated Double Networks

Reversibly Stretchable Organohydrogel-Based Soft Electronics with Robust and Redox-Active Interfaces Enabled by Polyphenol-Incorporated Double Networks

Vertical Graphene Film Enables High-Performance Quasi-Solid-State Planar Zinc-Ion Microbatteries

Integration of all‐printed zinc ion microbattery and glucose sensor toward onsite quick detections

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