Achieving High‐Voltage and High‐Capacity Aqueous Rechargeable Zinc Ion Battery by Incorporating Two‐Species Redox Reaction

Ma, Longtao; Chen, Shengmei; Long, Changbai; Li, Xinliang; Zhao, Yuwei; Liu, Zhuoxin; Huang, Zhaodong; Dong, Binbin; Zapien, Juan Antonio; Chen, Zhi

doi:10.1002/aenm.201902446

Cited by 361 publications

(282 citation statements)

References 54 publications

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“…As the cycle progresses, by the 10 th cycle, broad redox peaks at 0.7/0.3V and 0.5/1.0-1.6 V appear, completely agreeing with the electrochemical behavior of V 2 CT X MXene in the previous study. [11,[29][30][31] Meanwhile, these features that Figure 3. Characterization of phase and structure transition of V 2 CT X MXene during further cycling.…”

Section: Resultsmentioning

confidence: 99%

“…Figure 4g reviews the rate performance of V-based aqueous zinc batteries reported in recent years. [30,37,39,[44][45][46][47][48][49][50][51][52] Our battery based on V 2 AlC cathode offers an excellent rate performance in aspects of both high capacities at a low current density and high current density toleration. In detail, the highest capacity of about 409.7 mAh g −1 with less than 25 mAh g −1 from the carbon cloth and additives can be obtained at 0.5 A g −1 .…”

Section: Resultsmentioning

confidence: 99%

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In Situ Electrochemical Synthesis of MXenes without Acid/Alkali Usage in/for an Aqueous Zinc Ion Battery

Yang

et al. 2020

Advanced Energy Materials

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The traditional method to fabricate a MXene based energy storage device starts from etching MAX phase particles with dangerous acid/alkali etchants to MXenes, followed by device assembly. This is a multistep protocol and is not environmentally friendly. Herein, an all‐in‐one protocol is proposed to integrate synthesis and battery fabrication of MXene. By choosing a special F‐rich electrolyte, MAX V2AlC is directly exfoliated inside a battery and the obtained V2CTX MXene is in situ used to achieve an excellent battery performance. This is a one‐step process with all reactions inside the cell, avoiding any contamination to external environments. Through the lifetime, the device experiences three stages of exfoliation, electrode oxidation, and redox of V2O5. While the electrode is changing, the device can always be used as a battery and the performance is continuously enhanced. The resulting aqueous zinc ion battery achieves outstanding cycling stability (4000 cycles) and rate performance (97.5 mAh g−1 at 64 A g−1), distinct from all reported aqueous MXene‐based counterparts with pseudo‐capacitive properties, and outperforming most vanadium‐based zinc ion batteries with high capacity. This work sheds light on the green synthesis of MXenes, provides an all‐in‐one protocol for MXene devices, and extends MXenes’ application in the aqueous energy storage field.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

In Situ Electrochemical Synthesis of MXenes without Acid/Alkali Usage in/for an Aqueous Zinc Ion Battery

Yang

et al. 2020

Advanced Energy Materials

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146

125

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“…M, Schematic of Zn//CoFe(CN) 6 MBs based on PAM electrolyte with and without F77, and, N, corresponding galvanostatic charge/discharge curves. (E‐G,L‐N) Reproduced with permission 30,52,55,59,62 . Copyright 2016, 2018, and 2019, Wiley‐VCH.…”

Section: Zinc Ion Mbsmentioning

confidence: 99%

“…The as‐fabricated MBs offered high specific capacity of 100.2 mAh/cm 3 and superior energy density of 195.39 mWh/cm 3 . To explore the new electrolyte for ensuring the mechanic strength of the MBs, Ma et al 62 invented a new‐type electrolyte (Figure 3M,N) of the PAM with poly (ethylene oxide) 53 ‐poly(propylene oxide) 34 ‐poly(ethylene oxide) (F77), which showed a distinct sol‐gel transition feature from 0°C to room temperature accompanied with the state change from aqueous to gel, contributing to the full utilization of the active material. As a result, this Zn//CoFe(CN) 6 MB delivered admirable long‐term cyclability (93.4% after 2000 cycles).…”

Section: Zinc Ion Mbsmentioning

confidence: 99%

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

Wang

2020

EcoMat

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In order to keep rapid pace with increasing demand of wearable and miniature electronics, zinc‐based microelectrochemical energy storage devices (MESDs), as a promising candidate, have gained increasing attention attributed to low cost, environmental benign, and high performance. Herein, this review summarizes the state‐of‐the‐art advances of zinc‐based MESDs in microbatteries (MBs) and microsupercapacitors and highlights merits of cost effectiveness and high performance for miniaturized smart integrated systems. First, an introduction is given to present importance of zinc‐based MESDs. Second, current status with representative fiber, in‐plane and sandwiched configurations are illustrated in detail, particularly with a focus on the reasonable construction of multifunctional MBs and microsupercapacitors and deep understanding of energy storage mechanisms. Then, achievements for smart systems are overviewed to highlight environmental adaptability, integratable properties, and scalability in targeting applications. Finally, critical perspectives and challenges on the synergistic optimization of whole device are discussed to demonstrate forward‐looking developmental directions of zinc‐based MESDs.

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“…These features endow the RZBs with the most competitive candidate for powering flexible and wearable devices. In the past decades, tremendous work was devoted to distinguishing a proper cathode for RZBs, manganese‐based oxides, 11,12 vanadium‐based oxides, 13‐15 cobalt‐base oxides, 16,17 molybdenum‐based materials, 18 prussian blue analogous, 19,20 and other materials. The advances in developing those materials broke many stereotypes, realizing high capacity, high voltage platform, and long lifespan 20‐22 .…”

Section: Introductionmentioning

confidence: 99%

Dendrites issues and advances in Zn anode for aqueous rechargeable Zn‐based batteries

Zhao

et al. 2020

EcoMat

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143

103

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Rechargeable Zn‐based batteries (RZBs) have attracted much attention and been regarded as one of the most promising candidates for next‐generation energy storage featured with high safety, low costs, environmental friendliness, and satisfactory energy density. The aqueous electrolyte system exhibits great potential to power the future wearable electronics. Apart from the achievements of high capacity cathode and stable electrolyte, the anode suffers from problems of dendrite growth, hydrogen evolution, and passivation with limited attention. The dendrite formation strongly restricts the battery lifespan. Therefore, strategies focused on dendrite suppression are carefully categorized and summarized in this review, including crystallographic orientation manipulation, electric field control, ion flux regulation, and mechanical shield. Each strategy and the detailed approaches are critically dissected. Finally, remaining challenges are emphasized in this review, expecting to supply further research with potential directions to fulfill the high performance of the Zn anodes.

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Achieving High‐Voltage and High‐Capacity Aqueous Rechargeable Zinc Ion Battery by Incorporating Two‐Species Redox Reaction

Cited by 361 publications

References 54 publications

In Situ Electrochemical Synthesis of MXenes without Acid/Alkali Usage in/for an Aqueous Zinc Ion Battery

In Situ Electrochemical Synthesis of MXenes without Acid/Alkali Usage in/for an Aqueous Zinc Ion Battery

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

Dendrites issues and advances in Zn anode for aqueous rechargeable Zn‐based batteries

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