A Semi‐solid Zinc Powder‐based Slurry Anode for Advanced Aqueous Zinc‐ion Batteries

Yang, Zefang; Zhang, Qi; Li, Wenbin; Xie, Chengzhi; Wu, Tingqing; Hu, Chao; Tang, Yougen; Wang, Haiyan

doi:10.1002/anie.202215306

Cited by 55 publications

(59 citation statements)

References 46 publications

(1 reference statement)

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“…This means that the optimized solvated Zn 2+ is more inclined to induce Zn deposition on the (002) plane compared with hydrated [(Zn(H 2 O) 6 ] 2+ . 35,36 Specifically, zinc metal with more (002) deposition may favor stable Zn stripping/plating in weakly acidic aqueous electrolytes. Importantly, the preferential adsorption of L-CN can cover the active sites on the anode surface, effectively preventing H 2 O occupation to avoid undesired side reactions.…”

Section: Energy and Environmental Science Papermentioning

confidence: 99%

Reversible adsorption with oriented arrangement of a zwitterionic additive stabilizes electrodes for ultralong-life Zn-ion batteries

Chen

et al. 2023

Energy Environ. Sci.

115

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Section: Energy and Environmental Science Papermentioning

confidence: 99%

Reversible adsorption with oriented arrangement of a zwitterionic additive stabilizes electrodes for ultralong-life Zn-ion batteries

Chen

et al. 2023

Energy Environ. Sci.

115

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“…However, zinc powder anode suffers from severe corrosion and hydrogen evolution due to the higher specific surface area and higher reactivity compared with the zinc foil anode. Therefore, some effective strategies have been exploited for the effective protection of zinc powder, such as semisolid zinc powder–based slurry, 62 the hybridization of commercial zinc powder and pristine graphene, 63 and spontaneous reaction of Zn powder and graphene oxide 64 …”

Section: Strategies For Dendrite‐free Zinc Anodementioning

confidence: 99%

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

Wang

Sun

2023

SusMat

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Zinc-based batteries are a very promising class of next-generation electrochemical energy storage systems, with high safety, eco-friendliness, abundant resources, and the absence of rigorous manufacturing conditions. However, practical applications of zinc-based rechargeable batteries are impeded by the low Coulombic efficiency, inferior cyclability, and poor rate capability, due to the instability of zinc anode. Herein, effective strategies for dendritefree zinc anode are symmetrically reviewed, especially highlighting specific mechanisms, delicate design of electrode and current collectors, controlled electrode|electrolyte interface, ameliorative electrolytes, and advanced separators design. First, the particular mechanisms of dendrites formation and the associated fundamentals of the stable Zn metal anodes are presented elaborately. Then, recent key strategies for dendrites prevention and hydrogen evolution reaction suppression are categorized, discussed, and analyzed in detail in view of the electrodes, electrolytes, and separators. Finally, the challenging perspectives and major directions of stable zinc anodes are briefly discussed for further industrialization and commercialization of zinc-based rechargeable batteries.

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“…Extensive efforts have been devoted to addressing the irreversibility issues of Zn anodes from the point of view of electrode-electrolyte interface 5,6 , solvation sheath [7][8][9][10] , crystallographic orientation 11,12 and electrode composition [13][14][15] , etc. For instance, formation of a high-quality solid-electrolyte interphase is an effective strategy to prolong lifespan and prevent irreversible losses caused by the nonuniform ions/atoms migration, side reactions and gas generation 16,17 .…”

Section: Mainmentioning

confidence: 99%

Atomically-ordered plating/stripping enables deep cycling zinc metal batteries

Chen

Xia

Zeng

et al. 2023

Preprint

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Metal anodes are emerging as culminating solutions for the development of energy-dense batteries in either aprotic, aqueous or solid battery configurations due to their fully active nature and lowest redox potential. However, unlike traditional intercalation electrodes, the low utilization of “hostless” metal anodes due to the intrinsically disordered plating/stripping has been impeding their practical applications. Herein, we report atomically-ordered plating/stripping in a bulk zinc (Zn) foil anode to achieve an extremely high depth of discharge (DODZn) exceeding 90% with negligible thickness fluctuation and long-term stable cycling. The topmost atomic layer of the Zn anode can be plated/stripped preferentially throughout the consecutive charge/discharge process, along with the dynamic formation and dissociation of interfacial bridge bonds assisted by a self-assembled supramolecular bilayer at the Zn anode-electrolyte interface. Through real-time tracking of the Zn atoms migration using ab initio molecular dynamics, we reveal that the atomically-ordered plating/stripping is driven by stepwise kinetic pathways originating from the construction of Zn–N bindings and the atomic gradient energy landscape at the reaction fronts. The breakthrough results provide atomic insights into the ordered and reversible plating/stripping of metal anodes toward rechargeable energy-dense metal batteries.

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A Semi‐solid Zinc Powder‐based Slurry Anode for Advanced Aqueous Zinc‐ion Batteries

Cited by 55 publications

References 46 publications

Reversible adsorption with oriented arrangement of a zwitterionic additive stabilizes electrodes for ultralong-life Zn-ion batteries

Reversible adsorption with oriented arrangement of a zwitterionic additive stabilizes electrodes for ultralong-life Zn-ion batteries

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

Atomically-ordered plating/stripping enables deep cycling zinc metal batteries

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