Recent progress of dendrite‐free stable zinc anodes for advanced zinc‐based rechargeable batteries: Fundamentals, challenges, and perspectives

Wang, Xiao; Sun, Chenglin; Wu, Zhong‐Shuai

doi:10.1002/sus2.118

Cited by 38 publications

(12 citation statements)

References 174 publications

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“…The cell with Ex‐GGE only runs 330 h with a quick overpotential increase during subsequent cycling due to the generation of interfacial gaps (Figure 5a). Upon introducing In‐GGE, the cell life is largely extended to 2080 h, which is far superior to the life of the one using a liquid electrolyte (121 h) [29] . At high charging capacities, the electrode‐electrolyte interfacial interspace is more severe after repeated cycling because of the volume effect of the zinc bulk.…”

Section: Resultsmentioning

confidence: 98%

Thermally Healable Electrolyte‐Electrode Interface for Sustainable Quasi‐Solid Zinc‐ion Batteries

Yang,

Zhang,

et al. 2024

Angew Chem Int Ed

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Quasi‐solid zinc‐ion batteries using hydrogel electrolytes show great potential in energy storage devices owing to their intrinsic safety, fewer side reactions and wide electrochemical windows. However, the dendrite issues on the zinc anodes cannot be fundamentally eliminated and the intrinsic anode‐electrolyte interfacial interspace is rarely investigated. Here, we design a dynamically healable gelatin‐based hydrogel electrolyte with a highly reversible sol‐gel transition, which can construct a conformal electrode‐electrolyte interface and further evolve into a stable solid‐solid interface by in‐situ solidification. The unique helical gelatin chain structure provides a uniform channel for zinc ion transport by the bridging effect of sulfate groups. As a consequence, the dynamically healable interface enables dendrite‐free zinc anodes and repeatedly repairs the anode‐electrolyte interfacial interspaces by the reversible sol‐gel transition of gelatin electrolyte to retain long‐lasting protection for sustainable zinc‐ion batteries.

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Section: Resultsmentioning

confidence: 98%

Thermally Healable Electrolyte‐Electrode Interface for Sustainable Quasi‐Solid Zinc‐ion Batteries

Yang,

Zhang,

et al. 2024

Angew Chem Int Ed

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“…[5][6][7] In general, the formation of Zn dendrites is typically determined by the nucleation and growth processes. [8][9][10] At the initial nucleation stage, Zn tends to randomly nucleate on the Zn electrode surface stemming from higher nucleation barrier. 8,11 Whereafter, such inhomogeneous nucleation may induce the irregular electric field distribution, which produces a large amount of Zn dendrites and "dead" Zn.…”

Section: Introductionmentioning

confidence: 99%

Dendrite‐free Zn deposition initiated by nanoscale inorganic–organic coating‐modified 3D host for stable Zn‐ion battery

Dong,

Duan,

Cao

et al. 2024

SusMat

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A 3D nanostructured scaffold as the host for zinc enables effective inhibition of anodic dendrite growth. However, the increased electrode/electrolyte interface area provided by using 3D matrices exacerbates the passivation and localized corrosion of the Zn anode, ultimately bringing about the degradation of the electrochemical performance. Herein, a nanoscale coating of inorganic–organic hybrid (α‐In2Se3‐Nafion) onto a flexible carbon nanotubes (CNTs) framework (ISNF@CNTs) is designed as a Zn plating/stripping scaffold to ensure uniform Zn nucleation, thus achieving a dendrite‐free and durable Zn anode. The introduced inorganic–organic interfacial layer is dense and sturdy, which hinders the direct exposure of deposited Zn to electrolytes and mitigates the side reactions. Meanwhile, the zincophilic nature of ISNF can largely reduce the nucleation energy barrier and promote the ion‐diffusion transportation. Consequently, the ISNF@CNTs@Zn electrode exhibits a low‐voltage hysteresis and a superior cycling life (over 1500 h), with dendrite‐free Zn‐plating behaviors in a typical symmetrical cell test. Additionally, the superior feature of ISNF@CNTs@Zn anode is further demonstrated by Zn‐MnO2 cells in both coin and flexible quasi‐solid‐state configurations. This work puts forward an inspired remedy for advanced Zn‐ion batteries.

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“…There has been an increasing amount of research for methods of mineral materials analysis in the last a few years 2,3 . However, most of them are accompanied by secondary pollution, which is detrimental to human health, and require high levels of expertise and technical skills from the testing personnel 4 . Due to the global Zn ore stone production approaching 600 million tons per year, secondary pollution and damage to human health resulted from sphalerite analysis cannot be ignored 5…”

Section: Introductionmentioning

confidence: 99%

“…2,3 However, most of them are accompanied by secondary pollution, which is detrimental to human health, and require high levels of expertise and technical skills from the testing personnel. 4 Due to the global Zn ore stone production approaching 600 million tons per year, secondary pollution and damage to human health resulted from sphalerite analysis cannot be ignored. 5 Presently, the composition of sphalerite can be determined using two series of methods.…”

Section: Introductionmentioning

confidence: 99%

A new method to determine composition of sphalerite without secondary pollution based on CIELAB color space

Liu,

Duan,

Jiang

et al. 2023

SusMat

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Currently, most of the methods for mineral materials analysis generate secondary pollution, which is detrimental to human health. For instance, traditional methods for sphalerite analysis in the zinc (Zn) smelting industry including chemical titration, atomic absorption spectrometry, and inductively coupled atomic emission spectroscopy. Colored indicators and toxic heavy metals are used in the analytical processes, causing severe pollution. For some methods, liquid is transformed into gaseous plasma, which is more dangerous to human health. Due to large quantities of sphalerite being used, secondary pollution cannot be ignored. This study proposes a green analysis method for the detection of sphalerite based on colorimetry, which does not generate secondary pollution. The results show that the strong substitution ability of iron (Fe) for Zn contributes to their inverse correlation in contents. The lattice parameters decrease with the increasing Fe content, resulting in a darker coloration. Here, key colorimetry parameters of L*, a*, and b* show clear linear correlations with the Zn and Fe contents. Compared with traditional approaches, this new method is environmental friendly with high sensitivity and accuracy. The relative error and relative standard deviation were less than 10% and 5%, respectively. This study provides a significant reference for nonpollution determination of other mineral materials.

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Recent progress of dendrite‐free stable zinc anodes for advanced zinc‐based rechargeable batteries: Fundamentals, challenges, and perspectives

Cited by 38 publications

References 174 publications

Thermally Healable Electrolyte‐Electrode Interface for Sustainable Quasi‐Solid Zinc‐ion Batteries

Thermally Healable Electrolyte‐Electrode Interface for Sustainable Quasi‐Solid Zinc‐ion Batteries

Dendrite‐free Zn deposition initiated by nanoscale inorganic–organic coating‐modified 3D host for stable Zn‐ion battery

A new method to determine composition of sphalerite without secondary pollution based on CIELAB color space

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