Electrochemical and Morphological Characterization of Zn−Al−Cu Layered Double Hydroxides as a Negative Electrode in Aqueous Zinc‐Ion Batteries

Hashemi, Amir Bani; Kasiri, Ghoncheh; Glenneberg, Jens; Langer, Frederieke; Kun, Róbert; Mantia, Fabio La

doi:10.1002/celc.201800291

Cited by 25 publications

(38 citation statements)

References 42 publications

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“…In another work, Cu‐doped Zn–Al–CO 3 layered double hydroxide (LDH) has also been fabricated by a co‐deposition method and mixed with Zn powders to suppress Zn dendrite formation. [ 58 ] The attraction to Zn 2+ from carbonate and the enlarged interface area provided by the LDH could facilitate the Zn nucleation and deposition. As a result, the overpotential of Zn deposition for the LDH‐modified anode was decreased compared to the pristine one, and a high CE of 98% was achieved.…”

Section: Dendrite Inhibition Strategies On Zn Anodementioning

confidence: 99%

Strategies for the Stabilization of Zn Metal Anodes for Zn‐Ion Batteries

Chen

Hou

et al. 2020

Advanced Energy Materials

478

374

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scenario, the utilization of alternative and sustainable energy types, such as solar energy, [2] wind energy, [3] biomass energy, [4] tidal energy, [5] and geothermal energy, [6] is essential. Although these types of energy are generally accessible and clean, the direct storage and transportation of them are extremely difficult, and their highly fluctuating nature makes things even worse. [7] Alternatively, electrical energy is often generated from these energy types and serves as an intermediate between the direct energy harvest and the terminal utilization. In this regard, the development of energy storage systems (ESSs) is essential to provide a more versatile and stable energy supply for individual, household, and industrial applications, which has consequently been extensively investigated. [8] Among all current ESSs, batteries play a major role [9] and have been indispensably utilized for portable electronics, tools, electric vehicles (EVs), and even power grids. [10] Owing to their lightweight, high energy density, and extended cycle life, lithium-ion batteries (LIBs), initially developed in the early 1990s, are regarded as a milestone of ESS technologies. [11] Since then, LIBs have been widely applied, which have reshaped our lifestyle. Despite their success in mass production, commercial LIBs still suffer from high cost due to the limited lithium resource and the high cost of other components (e.g., Co-based cathode), [12] which is further worsened by the rigid requirement for their manufacture. Besides, the safety concerns, which stem from the flammable organic electrolyte and highly reactive lithium species, also significantly hinder the deployment of LIBs on a large scale. [13] Considering these limitations of LIBs, it is necessary to develop alternative ESSs with comparable energy/power density but better costeffectiveness and higher safety characteristics. [14] To achieve this, the exploration of high capacity yet relatively inert anode materials and nonflammable electrolytes is essential. Zinc-ion batteries (ZIBs) have been prospected as a new generation of inexpensive and safe ESS devices. Different from typical LIBs, a ZIB is composed of a Zn 2+ ion storage cathode and a Zn metal anode, which is favorable for high anode capacity. Furthermore, aqueous electrolytes are frequently used for ZIBs rather than the organic ones. [15] As a result, energy is stored and released via the reversible Zn stripping/plating at the anode and Zn 2+ insertion/desertion at Zinc-ion batteries (ZIBs) are regarded as a promising candidate for next-generation energy storage systems due to their high safety, resource availability, and environmental friendliness. Nevertheless, the instability of the Zn metal anode has impeded ZIBs from being reliably deployed in their proposed applications. Specifically, dendrite formation and the hydrogen evolution reaction (HER) on the Zn surface significantly compromise the Coulombic efficiency and cycling stability of ZIBs. In recent years, increasing efforts have been devoted t...

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Section: Dendrite Inhibition Strategies On Zn Anodementioning

confidence: 99%

Strategies for the Stabilization of Zn Metal Anodes for Zn‐Ion Batteries

Chen

Hou

et al. 2020

Advanced Energy Materials

478

374

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“…此外 , 潘峰团队 [101] Hashemi等 [106] 通过共沉淀法制备了Zn-Al-CO 3 层状双氢氧化物(LDH), 并将其作为添加剂与锌粉制备为锌负极. 研究发现, LDH层状结构不仅可以为Zn 2＋沉积提供更多的位点, 而且降低反应过电位, 使负极的库伦效率提高到了98%.…”

Section: 引言unclassified

Research Progress and Challenge of Aqueous Zinc Ion Battery

Zhang¹,

Wang²,

Zhang³

et al. 2021

Acta Chimica Sinica

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Aqueous zinc ion batteries (AZIBs) as an emerging battery energy storage technology have attracted widespread attention and developed rapidly in recent years due to the merits of high safety, low price, high energy density, environmental friendliness, easy manufacturing, etc., showing good application value and prospect in large-scale energy storage and other fields. Embarking from the current scientific issues existed in AZIBs, we review the important progress in cathode and anode materials and electrolyte used in AZIBs in this article. Firstly, the characteristics of multiple cathode materials that developed and their electrochemical reaction mechanism are analyzed and summarized. Afterward, the challenge and improving strategy for metal zinc anode are discussed, and the features of different aqueous electrolytes and the optimization solution are analyzed. Finally, the scientific problems to solve and technical challenges for the practical application in the future of this novel battery technology are summarized and prospected.

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“…This is due to the low cost of metallic zinc, being an earth-abundant element, to its high volumetric and gravimetric capacity (of 5855 mAh cm −3 and of 820 mAh g −1 , respectively), and to its low standard reduction potential (− 0.76 V vs. SHE), which still allows the operation of the battery in aqueous electrolytes [5,8]. Despite the fact that the application of aqueous Zn-ion batteries is mostly limited by the lack of efficient Zn insertion materials with long cycle life, to be used in the positive electrode side [5], many limitations still need to be overcome on the negative electrode side as well [9][10][11]. The major problems yet to be solved involving the metallic zinc electrode are related to the hydrogen evolution reaction occurring in parallel to the Zn deposition reaction [9][10][11], and the non-uniform deposition of metallic Zn leading to the formation of dendrites, and consequently to short-circuit of the electrodes [11].…”

Section: Introductionmentioning

confidence: 99%

“…Despite the fact that the application of aqueous Zn-ion batteries is mostly limited by the lack of efficient Zn insertion materials with long cycle life, to be used in the positive electrode side [5], many limitations still need to be overcome on the negative electrode side as well [9][10][11]. The major problems yet to be solved involving the metallic zinc electrode are related to the hydrogen evolution reaction occurring in parallel to the Zn deposition reaction [9][10][11], and the non-uniform deposition of metallic Zn leading to the formation of dendrites, and consequently to short-circuit of the electrodes [11]. Despite the fact that the zinc deposition and dissolution reaction has been studied for decades, mainly for corrosion and electrodeposition applications [12][13][14][15][16][17], further investigations are yet needed regarding the Zn reaction mechanisms in the solutions employed within the Zn-ion batteries.…”

Section: Introductionmentioning

confidence: 99%

Fast electrodeposition of zinc onto single zinc nanoparticles

Zampardi

Compton

2020

J Solid State Electrochem

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The zinc deposition reaction onto metallic zinc has been investigated at the single particle level through the electrode-particle collision method in neutral solutions, and in respect of its dependence on the applied potential and the ionic strength of a sulphatecontaining solution. Depending on the concentration of sulphate ions in solution, different amounts of metallic zinc were deposited on the single Zn nanoparticles. Specifically, insights into the electron transfer kinetics at the single particles were obtained, indicating an electrically early reactant-like transition state, which is consistent with the rate-determining partial dehydration/de-complexation process. Such information on the reaction kinetics at the nanoscale is of vital importance for the development of more efficient and long-lasting nanostructured Zn-based negative electrodes for Zn-ion battery applications.

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Electrochemical and Morphological Characterization of Zn−Al−Cu Layered Double Hydroxides as a Negative Electrode in Aqueous Zinc‐Ion Batteries

Cited by 25 publications

References 42 publications

Strategies for the Stabilization of Zn Metal Anodes for Zn‐Ion Batteries

Strategies for the Stabilization of Zn Metal Anodes for Zn‐Ion Batteries

Research Progress and Challenge of Aqueous Zinc Ion Battery

Fast electrodeposition of zinc onto single zinc nanoparticles

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