Functionalized Zn@ZnO Hexagonal Pyramid Array for Dendrite‐Free and Ultrastable Zinc Metal Anodes

Kim, Ji Young; Liu, Guicheng; Shim, Ga Young; Kim, Han Sung; Lee, Joong Kee

doi:10.1002/adfm.202004210

Cited by 164 publications

(105 citation statements)

References 60 publications

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“…Similarly, an array of hexagonal-pyramid-structured ZnO was coated on Zn surface by periodic anodization (Figure 9d). [60] The ZnO layers are thin on top and became thicker toward their bottom, and such a gradient structure can effectively regulate the Zn deposition by impeding the Zn deposition on the top of the array by increasing the charge transfer resistance but facilitating the Zn deposition at the bottom. Due to these advantages, the dendrite formation on this ZnO-modified anode could be alleviated, and the battery life can be extended.…”

Section: Nonconductive Coating For Dendrite Suppressionmentioning

confidence: 99%

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

Chen

Hou

et al. 2020

Advanced Energy Materials

531

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: Nonconductive Coating For Dendrite Suppressionmentioning

confidence: 99%

mentioning

confidence: 99%

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

Chen

Hou

et al. 2020

Advanced Energy Materials

531

374

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“…Heat treatment is required to crystallize the oxide (300 °C for 1 h) [ 75 ]. Zn/ZnO-hexagonal pyramid array for a Zn-ion battery anode was created by Kim et al [ 76 ] by applying pulsed-galvanostatic anodization in an aqueous solution containing NH 4 Cl and H 2 O 2 . The main parameter used to control the Zn periodic anodizing process was the time ratio between current-on/current-off with a continuous period of 6 s. The anodization was performed for 1 min.…”

Section: General Aspects Of Anodic Oxide Synthesis For Energy Applmentioning

confidence: 99%

“…Regarding other anodized oxides, some studies described the use of nanostructured WO 3 and Sn@Cu x O in LIBs [ 72 , 79 ], SnO x , and Nb 2 O 5 in SIBs [ 148 , 149 , 151 ], and ZnO in ZIBs [ 76 ]. Due to its high theoretical capacity (696 mA·h·g −1 ) [ 72 ], WO 3 is also a potential material for anodes in LIBs.…”

Section: Energy Storage Devices: Supercapacitors and Batteriesmentioning

confidence: 99%

“…Zn-ion batteries are considered a green energy system [ 76 ] using less-flammable electrolytes and low-toxic materials. Kim et al [ 76 ] used the periodic anodizing technique to produce ultra-stable Zn anode in a hexagonal pyramid arrangement with a functionalized ZnO layer for a ZIB device. This structure inhibited the growth of Zn dendrites, which damage the electrode stability.…”

Section: Energy Storage Devices: Supercapacitors and Batteriesmentioning

confidence: 99%

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The Use of Anodic Oxides in Practical and Sustainable Devices for Energy Conversion and Storage

et al. 2021

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This review addresses the main contributions of anodic oxide films synthesized and designed to overcome the current limitations of practical applications in energy conversion and storage devices. We present some strategies adopted to improve the efficiency, stability, and overall performance of these sustainable technologies operating via photo, photoelectrochemical, and electrochemical processes. The facile and scalable synthesis with strict control of the properties combined with the low-cost, high surface area, chemical stability, and unidirectional orientation of these nanostructures make the anodized oxides attractive for these applications. Assuming different functionalities, TiO2-NT is the widely explored anodic oxide in dye-sensitized solar cells, PEC water-splitting systems, fuel cells, supercapacitors, and batteries. However, other nanostructured anodic films based on WO3, CuxO, ZnO, NiO, SnO, Fe2O3, ZrO2, Nb2O5, and Ta2O5 are also explored and act as the respective active layers in several devices. The use of AAO as a structural material to guide the synthesis is also reported. Although in the development stage, the proof-of-concept of these devices demonstrates the feasibility of using the anodic oxide as a component and opens up new perspectives for the industrial and commercial utilization of these technologies.

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Fast‐Charging and Ultrahigh‐Capacity Zinc Metal Anode for High‐Performance Aqueous Zinc‐Ion Batteries

Cao

Zhou

Wei³

et al. 2021

Adv Funct Materials

232

166

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Although some strategies have been triggered to address the intrinsic drawbacks of zinc (Zn) anodes in aqueous Zn‐ion batteries (ZIBs), the larger issue of Zn anodes unable to cycle at a high current density with large areal capacity is neglected. Herein, the zinc phosphorus solid solution alloy (ZnP) coated on Zn foil (Zn@ZnP) prepared via a high‐efficiency electrodeposition method as a novel strategy is proposed. The phosphorus (P) atoms in the coating layer are beneficial to fast ion transfer and reducing the electrochemical activation energy during Zn stripping/plating processes. Besides, a lower energy barrier of Zn2+ transferring into the coating can be attained due to the additional P. The results show that the as‐prepared Zn@ZnP anode in the symmetric cell can be cycled at a current density of 15 mA cm−2 with an areal capacity of 48 mAh cm−2 (depth of discharge, DOD ≈ 82%) and even at an ultrahigh current density of 20 mA cm−2 and DOD ≈ 51%. Importantly, a discharge capacity of 154.4 mAh g−1 in the Zn/MnO2 full cell can be attained after 1000 cycles at 1 A g−1. The remarkable effect achieved by the developed strategy confirms its prospect in the large‐scale application of ZIBs for high‐power devices.

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Functionalized Zn@ZnO Hexagonal Pyramid Array for Dendrite‐Free and Ultrastable Zinc Metal Anodes

Cited by 164 publications

References 60 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

The Use of Anodic Oxides in Practical and Sustainable Devices for Energy Conversion and Storage

Fast‐Charging and Ultrahigh‐Capacity Zinc Metal Anode for High‐Performance Aqueous Zinc‐Ion Batteries

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