Tuning the Electrolyte Solvation Structure to Suppress Cathode Dissolution, Water Reactivity, and Zn Dendrite Growth in Zinc‐Ion Batteries

Liu, Sailin; Mao, Jianfeng; Pang, Wei; Vongsvivut, Jitraporn; Zeng, Xiaohui; Thomsen, Lars; Wang, Yanyan; Liu, Jianwen; Li, Dan; Guo, Zaiping

doi:10.1002/adfm.202104281

Cited by 250 publications

(239 citation statements)

References 40 publications

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“…Electrolyte additives are used to adjust the surface morphology of the Zn anode and inhibit side reactions, such as Zn dendrite growth, hydrogen evolution reaction, and Zn surface corrosion and passivation. Various electrolyte additives have been applied to RAZIBs to protect the Zn [84] anode by electrostatic shielding, crystallographic orientation induction, and modulation of the coordination status mechanism. According to previous research results, electrolyte additives can be divided into ionic and non-ionic additives.…”

Section: Interface Modification Of Electrolyte/zn Anode By Electrolyte Additivesmentioning

confidence: 99%

“…Some additives can replace H 2 O in the Zn 2+ -solvated sheath, preferentially solvate with Zn ions, and remove H 2 O from the Zn 2+ -solvated sheath [ 83 ]. In addition, some additives also have a strong interaction with water, which reduces water activity and effectively inhibits parasitic water reactions and dendrite growth [ 84 ]. Furthermore, an in situ solid electrolyte interphase (SEI) layer can be constructed by adding additives to the electrolyte.…”

Section: Protection Mechanism Of Interfacial Engineeringmentioning

confidence: 99%

“…Furthermore, an in situ solid electrolyte interphase (SEI) layer can be constructed by adding additives to the electrolyte. The presence of additives not only adjusts the structure of the solvent sheath of Zn ions, allowing the rapid transmission of Zn 2+ , but also prevents H 2 O from penetrating the surface of the Zn anode, which greatly reduces the probability of side reactions [ 83 , 84 ].…”

Section: Protection Mechanism Of Interfacial Engineeringmentioning

confidence: 99%

“…13 f). Mao et al [ 84 ] used the flame-retardant triethyl phosphate (TEP) as a co-solvent by adjusting the solvation structure of the non-aqueous electrolyte. TEP preferentially forms a TEP-occupied inner solvation sheath around Zn 2+ and strong H bonding with H 2 O (Fig.…”

Section: Surface Modification Of Zn Anodementioning

confidence: 99%

“…Characterization of the interphase on the cycled Zn surface: h XPS fitted curves of the F 1s, C 1s, and P 2p elements and i the interference reflection microscopy spectrum of the cycled Zn electrode and the acquired distribution of surface functional groups. Copyright 2021 Wiley-VCH [ 84 ] …”

Section: Surface Modification Of Zn Anodementioning

confidence: 99%

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Interfacial Engineering Strategy for High-Performance Zn Metal Anodes

et al. 2021

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Due to their high safety and low cost, rechargeable aqueous Zn-ion batteries (RAZIBs) have been receiving increased attention and are expected to be the next generation of energy storage systems. However, metal Zn anodes exhibit a limited-service life and inferior reversibility owing to the issues of Zn dendrites and side reactions, which severely hinder the further development of RAZIBs. Researchers have attempted to design high-performance Zn anodes by interfacial engineering, including surface modification and the addition of electrolyte additives, to stabilize Zn anodes. The purpose is to achieve uniform Zn nucleation and flat Zn deposition by regulating the deposition behavior of Zn ions, which effectively improves the cycling stability of the Zn anode. This review comprehensively summarizes the reaction mechanisms of interfacial modification for inhibiting the growth of Zn dendrites and the occurrence of side reactions. In addition, the research progress of interfacial engineering strategies for RAZIBs is summarized and classified. Finally, prospects and suggestions are provided for the design of highly reversible Zn anodes.

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Section: Interface Modification Of Electrolyte/zn Anode By Electrolyte Additivesmentioning

confidence: 99%

Section: Protection Mechanism Of Interfacial Engineeringmentioning

confidence: 99%

Section: Protection Mechanism Of Interfacial Engineeringmentioning

confidence: 99%

Section: Surface Modification Of Zn Anodementioning

confidence: 99%

Section: Surface Modification Of Zn Anodementioning

confidence: 99%

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Interfacial Engineering Strategy for High-Performance Zn Metal Anodes

et al. 2021

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Unraveling the Rate‐Dependent Stability of Metal Anodes and Its Implication in Designing Cycling Protocol

Hou

Gao

Zhou

et al. 2021

Adv Funct Materials

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It is widely recognized that a high current rate (J) speeds up dendrite formation and thus shortens the cycle life of metal anodes. Here, an anomalous correlation is reported between elevated J and deposition/ stripping stability (decrease-increase-decrease), leading to the relative maximum stability at a moderate J. Complementary theoretical and experimental analyses suggest that such a complex relationship lies in high J's dual and contradictory roles in kinetics and thermodynamics. The wellknown former renders decreased Sand's time (τ) and deteriorative cyclic stability, while the commonly overlooked latter provides larger extra energy that accelerates nucleation rate (ν n ). Using Zn metal anode as a model system, the ν n and τ controlled nucleation-growth process is unambiguously revealed, both of which are closely related to J. Based on these findings, an initial high J discharge strategy is developed to produce abundant nuclei for uniform metal growth at standard J in the subsequent process. The protocol increases the Zn deposition/stripping lifetime from 303 to 2500 h under a cycling capacity of 1 mAh cm −2 without resorting to electrode/electrolyte modification. Furthermore, such a concept can be readily extended to Li/K metal anodes with significantly enhanced cycle life, demonstrating its universality for developing high-performance metal batteries.

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Regulating the Electrolyte Solvation Structure Enables Ultralong Lifespan Vanadium‐Based Cathodes with Excellent Low‐Temperature Performance

Liu

Zhang

Liu

et al. 2022

Adv Funct Materials

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Aqueous Zn||vanadium oxide batteries (ZVBs) have recently received considerable attention owing to their high capacity, safety, environmental friendliness, and cost effectiveness. However, the limited cycling stability caused by the irreversible dissolution in traditional aqueous electrolytes still restricts their further application. Herein, a novel 3 m Zn(CF3SO3)2 electrolyte with a mixture solvent of propylene carbonate (PC) and H2O is adopted for aqueous vanadium‐based zinc‐ion batteries. With the manipulation of the electrolyte solvation structure, the optimized P20 (20% PC in volume ratio) electrolyte enables super‐stable cycling performance with high‐capacity retention of 99.5%/97% after 100/1000 cycles at 0.1/5 A g−1 at ambient environment in the Zn||NaV3O8·1.5H2O batteries. Systematical electrochemical testing and characterizations illustrate the addition of PC effectively reduces the active water molecule in Zn2+‐solvent cations and H+ in the electrolyte, thereby suppressing the cathode dissolution caused by the inserted H+ and co‐inserted H2O during the discharge/charge process. Impressively, the PC addition also enabled the Zn||NaV3O8·1.5H2O batteries present high specific capacity of 183/168 mAh g‐1 and high‐capacity retention of 100%/100% over 300/400 cycles at 0.1/0.2 A g‐1 at −40 °C, thus efficiently broadening the practical application for ZVB. This research may provide a promising strategy for designing high‐performance electrolytes for aqueous vanadium‐based batteries.

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Tuning the Electrolyte Solvation Structure to Suppress Cathode Dissolution, Water Reactivity, and Zn Dendrite Growth in Zinc‐Ion Batteries

Cited by 250 publications

References 40 publications

Interfacial Engineering Strategy for High-Performance Zn Metal Anodes

Interfacial Engineering Strategy for High-Performance Zn Metal Anodes

Unraveling the Rate‐Dependent Stability of Metal Anodes and Its Implication in Designing Cycling Protocol

Regulating the Electrolyte Solvation Structure Enables Ultralong Lifespan Vanadium‐Based Cathodes with Excellent Low‐Temperature Performance

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