Achieving Ultrahigh‐Rate Planar and Dendrite‐Free Zinc Electroplating for Aqueous Zinc Battery Anodes

Pu, Shengda D.; Chen, Gong; Tang, Yuanbo T.; Ning, Ziyang; Liu, Junliang; Zhang, Shengming; Yuan, Yi; Melvin, Dominic L. R.; Yang, Sixie; Pi, Liquan; Marie, John‐Joseph; Hu, Bing; Jenkins, Max; Li, Zixuan; Liu, Boyang; Tsang, Shik Chi Edman; Marrow, T J; Reed, Roger C.; Gao, Xiangwen; Bruce, Peter G.; Robertson, Alex W.

doi:10.1002/adma.202202552

Cited by 128 publications

(102 citation statements)

References 65 publications

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“…It is noted that a certain amorphous structure might still exist on the Zn electrodes which is not detected by XRD. The intensity proportion of (002) Zn and (100) Zn peaks of the Zn deposition is enhanced after the addition of acetate additives, suggesting the preferential deposition of (002) Zn planes as shown in Figure a–f which is consistent with previous reports. , Moreover, the (002) Zn /(100) Zn proportion of Zn deposition increases along with cycling (Figure S15), which enables homogeneous Zn deposition and stable cycling as discussed in Figure d,e.…”

Section: Resultssupporting

confidence: 91%

Unraveling the Interphasial Chemistry for Highly Reversible Aqueous Zn Ion Batteries

Zhao

Dong

Yan

et al. 2023

ACS Appl. Mater. Interfaces

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A robust solid electrolyte interface (SEI) is crucial to widen the electrochemical stability window of the electrolyte and enable sustainably stable electrode reactions in aqueous Zn ion batteries. Different from the SEI in nonaqueous electrolytes, it is of great importance to form a functional and stable SEI due to parasitic reactions with water in aqueous Zn ion batteries. However, the concrete SEI formation in aqueous electrolytes has been elusive so far. Here, we regulate and unravel the decomposition mechanisms of organic Zn salts at the Zn anode− electrolyte interface in the widely studied zinc triflate-based aqueous electrolytes. By introducing a buffering adsorption layer with an optimal concentration of acetate anions, the uncontrollable decomposition of organic zinc triflate salt is greatly inhibited on Zn anodes, resulting in a stable interface. The average Coulombic efficiency of the Zn anode thus can reach as high as 99.95% and stable cycling for 4200 h. With the cooperation of buffering adsorption layers, the tetraethyl ammonium trifluoromethanesulfonate additive as the decomposition promoter could further regulate the decomposition of triflate anions for the formation of robust SEI layers for Zn anodes in electrolytes with a dilute salt concentration. Zn−polyaniline (PANI) full cells demonstrate stable cycling with controlled N/P ratios in such electrolytes. This work proposes an insightful perspective on rational regulation of the decomposition pathway of electrolyte components by forming a stable electrode−electrolyte interface for improved electrochemical performance of aqueous Zn ion batteries.

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Section: Resultssupporting

confidence: 91%

Unraveling the Interphasial Chemistry for Highly Reversible Aqueous Zn Ion Batteries

Zhao

Dong

Yan

et al. 2023

ACS Appl. Mater. Interfaces

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“…5(a) and (b)), leading to the formation of a homoepitaxial layer rather than the case of current collector design via heteroepitaxy. 93 In this realm, many efforts have been made to regulate Zn deposition morphology at the Zn/electrolyte interface.…”

Section: Strategies For the Orientational Deposition Of Znmentioning

confidence: 99%

Emerging strategies for steering orientational deposition toward high-performance Zn metal anodes

Zou

Yang

Shen

et al. 2022

Energy Environ. Sci.

152

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“…The Zn (0 0 1) facet exhibits the lowest surface energy among all zinc crystal facets, which infers that the Zn (0 0 1) facet tends to be preferentially exposed during the zinc nucleation stage based on crystal growth theory and can provide a substrate for homoepitaxial growth for subsequent Zn (0 0 1) facet growth. [24] At a high zinc deposition capacity, the active deposition sites of copper are occupied by zinc and the subsequent zinc is deposited not on copper surface but on the previously deposited zinc. Zn (0 0 1) texture is formed on PCu at the initial stage of zinc nucleation and the zinc deposits still consist of stacked hexagonal flakes by the continuous homoepitaxial growth of Zn (0 0 1) even though the deposition capacity increases.…”

Section: The Zinc Deposition Mechanism On Pcumentioning

confidence: 99%

High‐Index Zinc Facet Exposure Induced by Preferentially Orientated Substrate for Dendrite‐Free Zinc Anode

Xie

Zhang

et al. 2022

Advanced Energy Materials

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Cu (1 1 1) facet exposure can promote zinc nucleation and uniformize zinc growth. [6] The expensive Cu (1 0 0) single-crystal has also been used to inhibit the generation of zinc dendrites. [7] However, there is a limited prospect for graphene, copper nanowires, copper foam, and copper single-crystal because of their high cost. [8] Therefore, it is essential to develop more efficient and low-cost substrate regulation strategies.Electrolytic copper foil is a widely used commercial current collector with mature fabrication technology and acceptable cost. [9] Selective facet exposure during the electrolysis of copper foils has been proven to be easily achievable in existing copper foil preparations. [10] It may be a promising method to prepare specially oriented copper foils by electrolysis for practical applications. Various facets such as (1 1 1), (2 0 0), (2 2 0), and (3 1 1) may be exposed during the copper electrolysis process. [11] If the zinc deposition activity of these facets is identified, zinc deposition can be efficiently regulated by selectively exposing the most active facet. In addition to the effect of substrate facet exposure on zinc deposition, the exposed zinc facets during the deposition process can also influence the subsequent zinc deposition because of the different activities of the different zinc facets. [12] Crystal growth theory suggests that the fast-growing crystalline facets tend to disappear gradually, while slow-growing facets are preferentially exposed. [13] This critical conclusion is usually overlooked by some researchers who determine the preferential growth or exposure of crystal facets only by the intensity of the X-ray diffraction (XRD) peaks. This approach is usually inadequate because the relative peak intensities of bulk samples are related to the grain alignment orientation. [14] Electron backscatter diffraction (EBSD) can be used to precisely analyze the correlation between crystal facet growth and exposure to understand the zinc growth mechanism during electrodeposition. Based on the above considerations, fabrication of copper substrates with high active facet exposure by electrolysis and in-depth study of zinc growth mechanism on substrates are important to enhance its reversibility for zinc plating and stripping.In this work, we reveal the highest zinc deposition activity of Cu (2 2 0) facet in comparison with other low-index crystal facets by optical microscopy and EBSD techniques. An industrial electrolysis method is proposed to construct Cu (2 2 0) substrate with highly preferential orientation, denoted as PCu. This uniformly oriented substrate with zincophilicity can playThe most commonly used zinc foil anode for aqueous zinc-ion batteries suffers from poor cycle stability and low zinc utilization. Zinc-plated anodes on the host materials with high zincophilicity and stability are receiving increasing attention to alleviate these above issues. Here, the high zinc deposition activity of Cu (2 2 0) is confirmed through experimental observations and theoretical cal...

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Achieving Ultrahigh‐Rate Planar and Dendrite‐Free Zinc Electroplating for Aqueous Zinc Battery Anodes

Cited by 128 publications

References 65 publications

Unraveling the Interphasial Chemistry for Highly Reversible Aqueous Zn Ion Batteries

Unraveling the Interphasial Chemistry for Highly Reversible Aqueous Zn Ion Batteries

Emerging strategies for steering orientational deposition toward high-performance Zn metal anodes

High‐Index Zinc Facet Exposure Induced by Preferentially Orientated Substrate for Dendrite‐Free Zinc Anode

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