Modifying the Zn anode with carbon black coating and nanofibrillated cellulose binder: A strategy to realize dendrite-free Zn-MnO2 batteries

Wang, Anran; Zhou, Weijun; Huang, Aixiang; Chen, Minfeng; Chen, Jizhang; Tian, Qinghua; Xu, Junling

doi:10.1016/j.jcis.2020.05.102

Cited by 124 publications

(85 citation statements)

References 53 publications

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“…designed a polymeric interphase layer composed of polyamide and Zn(TfO) 2 , which can not only regulate Zn deposition, but also protect the surface of the deposited Zn from the electrolyte. [ 16 ] Besides, constructing coating layers including metal–organic frameworks (MOFs), [ 17 ] nanoporous CaCO 3 , [ 18 ] poly(vinyl butyral), [ 19 ] ZnO, [ 20 ] ZnS, [ 21 ] carbon black, [ 22 ] indium‐based compounds [ 23 ] and TiO 2 /PVDF composite [ 24 ] have also been proved to be effective in delaying Zn dendrite formation and improving electrochemical performance. However, these protective layers may be cracked during long‐term cycling especially at high current densities due to the drastic volume change during Zn deposition/stripping.…”

Section: Figurementioning

confidence: 99%

Synergistic Manipulation of Zn²⁺ Ion Flux and Desolvation Effect Enabled by Anodic Growth of a 3D ZnF₂ Matrix for Long‐Lifespan and Dendrite‐Free Zn Metal Anodes

et al. 2021

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Aqueous rechargeable Zn metal batteries have attracted widespread attention due to the intrinsic high volumetric capacity, low cost, and high safety. However, the low Coulombic efficiency and limited lifespan of Zn metal anodes resulting from uncontrollable growth of Zn dendrites impede their practical application. In this work, a 3D interconnected ZnF2 matrix is designed on the surface of Zn foil (Zn@ZnF2) through a simple and fast anodic growth method, serving as a multifunctional protective layer. The as‐fabricated Zn@ZnF2 electrode can not only redistribute the Zn2+ ion flux, but also reduce the desolvation active energy significantly, leading to stable and facile Zn deposition kinetics. The results reveal that the Zn@ZnF2 electrode can effectively inhibit dendrites growth, restrain the hydrogen evolution reactions, and endow excellent plating/stripping reversibility. Accordingly, the Zn@ZnF2 electrode exhibits a long cycle life of over 800 h at 1 mA cm−2 with a capacity of 1.0 mAh cm−2 in a symmetrical cell test, the feasibility of which is also convincing in Zn@ZnF2//MnO2 and Zn@ZnF2//V2O5 full batteries. Importantly, a hybrid zinc‐ion capacitor of the Zn@ZnF2//AC can work at an ultrahigh current density of ≈60 mA cm−2 for up to 5000 cycles with a high capacity retention of 92.8%.

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Section: Figurementioning

confidence: 99%

Synergistic Manipulation of Zn²⁺ Ion Flux and Desolvation Effect Enabled by Anodic Growth of a 3D ZnF₂ Matrix for Long‐Lifespan and Dendrite‐Free Zn Metal Anodes

et al. 2021

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“…The carbon-based materials such as CNTs, [241] rGO, [242] and carbon black [243] have also been proposed as the suitable candidates for the coating of Zn anode to minimize the issues associated with Zn. The experimental and theoretical studies show that the CNT coating completely inhibits the dendrite formation due to its charge redistribution effect on overpotential.…”

Section: Surface Tailoringmentioning

confidence: 99%

Aqueous Rechargeable Zn‐ion Batteries: Strategies for Improving the Energy Storage Performance

Mallick

Raj

2021

ChemSusChem

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The growing demand for the renewable energy storage technologies stimulated the quest for efficient energy storage devices. In recent years, the rechargeable aqueous zinc-based battery technologies are emerging as a compelling alternative to the lithium-based batteries owing to safety, eco-friendliness, and cost-effectiveness. Among the zinc-based energy devices, rechargeable zinc-ion batteries (ZIBs) are drawing considerable attention. However, they are plagued with several issues, including cathode dissolution, dendrite formation, etc.. Despite several efforts in the recent past, ZIBs are still in their infant stages and have yet to reach the stage of large-scale production. Finding stable Zn 2 + intercalation cathode material with high operating voltage and long cycling stability as well as dendrite-free Zn anode is the main challenge in the develop-ment of efficient zinc-ion storage devices. This Review discusses the various strategies, in terms of the engineering of cathode, anode and electrolyte, adopted for improving the charge storage performance of ZIBs and highlights the recent ZIB technological innovations. A brief account on the history of zinc-based devices and various cathode materials tested for ZIB fabrication in the last five years are also included. The main focus of this Review is to provide a detailed account on the rational engineering of the electrodes, electrolytes, and separators for improving the charge storage performance with a future perspective to achieving high energy density and long cycling stability and large-scale production for practical application.

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“…Modifying the traditional zinc foil (ZF) anode with carbon black coating and nanofibrous cellulose binder (ZF@CB‐NFC) can also effectively inhibit dendritic growth. [ 81 ] Benefitting from this modification method, the electric active surface area is greatly enhanced and the charge transfer is promoted, and therefore the cycle performance of the battery is improved. Choi and coworkers [ 82 ] electrodeposited MoS 2 coating on zinc plate as an anode material.…”

Section: The Strategies Of Suppressing Dendritesmentioning

confidence: 99%

Micronanostructured Design of Dendrite‐Free Zinc Anodes and Their Applications in Aqueous Zinc‐Based Rechargeable Batteries

Cui

Han

2021

Small Structures

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Aqueous zinc‐based rechargeable batteries are considered to be one of the most promising new energy storage systems due to their unique advantages (e.g., low cost, high safety, environmental friendliness, and high energy density). However, the formation of zinc dendrites at the anode during the operation can puncture the separator and even cause short circuit of batteries, which is one of the serious problems in Zn‐based batteries. Therefore, understanding the growth process of dendrites and suppressing the formation of zinc dendrites are necessary for the further development and large‐scale applications of Zn‐based batteries. Herein, the growth mechanism and the influence factors of zinc dendrites are first introduced in detail by combining the experimental and theoretical results. Moreover, the effective strategies for suppressing dendrites through micronanostructured design are summarized, including surface modification, alloying, and substrate selection/porous structure engineering. In the end, the challenges in the further development of high‐performance dendrite‐free zinc anode are discussed, and the research frontiers trends are prospected as well. It is aimed to shed light on the rational design and structure tuning of high‐performance zinc electrode materials for advanced zinc‐based secondary batteries for clean energy storage technologies.

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Modifying the Zn anode with carbon black coating and nanofibrillated cellulose binder: A strategy to realize dendrite-free Zn-MnO2 batteries

Cited by 124 publications

References 53 publications

Synergistic Manipulation of Zn²⁺ Ion Flux and Desolvation Effect Enabled by Anodic Growth of a 3D ZnF₂ Matrix for Long‐Lifespan and Dendrite‐Free Zn Metal Anodes

Synergistic Manipulation of Zn²⁺ Ion Flux and Desolvation Effect Enabled by Anodic Growth of a 3D ZnF₂ Matrix for Long‐Lifespan and Dendrite‐Free Zn Metal Anodes

Aqueous Rechargeable Zn‐ion Batteries: Strategies for Improving the Energy Storage Performance

Micronanostructured Design of Dendrite‐Free Zinc Anodes and Their Applications in Aqueous Zinc‐Based Rechargeable Batteries

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Modifying the Zn anode with carbon black coating and nanofibrillated cellulose binder: A strategy to realize dendrite-free Zn-MnO2 batteries

Cited by 124 publications

References 53 publications

Synergistic Manipulation of Zn2+ Ion Flux and Desolvation Effect Enabled by Anodic Growth of a 3D ZnF2 Matrix for Long‐Lifespan and Dendrite‐Free Zn Metal Anodes

Synergistic Manipulation of Zn2+ Ion Flux and Desolvation Effect Enabled by Anodic Growth of a 3D ZnF2 Matrix for Long‐Lifespan and Dendrite‐Free Zn Metal Anodes

Aqueous Rechargeable Zn‐ion Batteries: Strategies for Improving the Energy Storage Performance

Micronanostructured Design of Dendrite‐Free Zinc Anodes and Their Applications in Aqueous Zinc‐Based Rechargeable Batteries

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Synergistic Manipulation of Zn²⁺ Ion Flux and Desolvation Effect Enabled by Anodic Growth of a 3D ZnF₂ Matrix for Long‐Lifespan and Dendrite‐Free Zn Metal Anodes

Synergistic Manipulation of Zn²⁺ Ion Flux and Desolvation Effect Enabled by Anodic Growth of a 3D ZnF₂ Matrix for Long‐Lifespan and Dendrite‐Free Zn Metal Anodes