Stable Zinc Anodes Enabled by a Zincophilic Polyanionic Hydrogel Layer

Yang, Jinzhu; Li, Jia; Zhao, Jianwei; Liu, Kang; Yang, Peihua; Fan, Hong Jin

doi:10.1002/adma.202202382

Cited by 199 publications

(154 citation statements)

References 68 publications

(114 reference statements)

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“…[5] Among them, surface modification of Zn anode is an effective approach to reconstruct the electrolyte-anode interface. The reported protective layers include inorganic metal compounds such as ZnS, [6] ZnF 2 , [7] CaCO 3 , [8] , CuO, [9] and TiO 2 , [10] and organic polymers like hydrogel, [11] polyamide, [12] and polyethylene oxide. [13] However, most coating layers increase the interfacial resistance and show low ionic conductivity.…”

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confidence: 99%

A Molecular‐Sieve Electrolyte Membrane enables Separator‐Free Zinc Batteries with Ultralong Cycle Life

et al. 2022

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The poor stability of the zinc‐metal anode is a main bottleneck for practical application of aqueous zinc‐ion batteries. Herein, a series of molecular sieves with various channel sizes are investigated as an electrolyte host to regulate the ionic environment of Zn2+ on the surface of the zinc anode and to realize separator‐free batteries. Based on the ZSM‐5 molecular sieve, a solid–liquid mixed electrolyte membrane is constructed to uniformize the transport of zinc ions and foster dendrite‐free Zn deposition. Side reactions can also be suppressed through tailoring the solvation sheath and restraining the activity of water molecules in electrolyte. A V2O5||ZSM‐5||Zn full cell shows significantly enhanced performance compared to cells using glass fiber separator. Specifically, it exhibits a high specific capacity of 300 mAh g−1, and a capacity retention of 98.67% after 1000 cycles and 82.67% after 3000 cycles at 1 A g−1. It is attested that zeolites (ZSM‐5, H‐β, and Bate) with channel sizes of 5–7 Å result in best cycle stability. Given the low cost and recyclability of the ZSM and its potent function, this work may further lower the cost and boost the industrial application of AZIBs.

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confidence: 99%

A Molecular‐Sieve Electrolyte Membrane enables Separator‐Free Zinc Batteries with Ultralong Cycle Life

et al. 2022

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“…To overcome these issues and achieve better performance of AZMBs, it is crucial to suppress the presence of free water. [8] Many strategies have been proposed forcing on reducing water activity and concentration, such as electrolyte additives, [9] "water-in-salt" electrolytes, [10] surface engineering, [11] deep eutectic electrolyte, [12] molecular-crowding electrolyte, [13] and organic electrolyte. [14] For example, dimethyl sulfoxide (DMSO) as an electrolyte additive was introduced into aqueous electrolyte to achieve robust H-bond network via the hydrogen bond between the hydrogen atom of water molecule and DMSO, which effectively reduces the activity of water molecules and suppresses the parasitic reactions.…”

mentioning

confidence: 99%

Triggering Zn²⁺ Unsaturated Hydration Structure via Hydrated Salt Electrolyte for High Voltage and Cycling Stable Rechargeable Aqueous Zn Battery

Yan

et al. 2022

Advanced Energy Materials

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Ocean‐like free water in conventional aqueous electrolytes limits operating voltage and induces parasitic reactions in rechargeable Zn metal batteries (AZMBs). Herein, a hydrated salt electrolyte (HSE), which suppresses the presence of free water and triggers an unsaturated hydration structure (Zn(H2O)n2+, n < 6), is proposed to circumvent the parasitic reactions occurring on the zinc anode and cathode and elevate the decomposition voltage (to ≈2.55 V vs Zn2+/Zn). In a full cell with a transition metal oxide cathode, the parasitic reactions of dissolution and diffusion of discharge products are inhibited, and high discharge capacity retention above 80% at 500 mA g‐1 and super‐stable Coulombic efficiency (average value ≈99.97%) are delivered. Moreover, when applied in a high‐voltage AZMB with zinc hexacyanoferrate cathode, the full cell yields an average output voltage above 1.8 V together with a 132.3 Wh kg‐1 energy density at 10 mA g‐1 and 1.78 V output voltage combining high energy density and power density (88.5 Wh kg‐1/106.2 W kg‐1). The exceptional electrochemical performance of HSE indicates rosy prospects for the prevention of parasitic reactions in AZMBs, a key step on the road to further commercialization of AZMBs.

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“…Combining the interfacial protection concept with hydrogels provides a distinct idea for stabilizing aqueous batteries. We used a polyanionic hydrogel thin film on a zinc metal anode as the protective layer (Figure c) . The hydrogel layer chemically bonded on the Zn metal surface possesses an anticatalysis effect, which effectively suppresses both the hydrogen evolution reaction and dendrite formation.…”

Section: Properties Of Smart Batteriesmentioning

confidence: 99%

“…We used a polyanionic hydrogel thin film on a zinc metal anode as the protective layer (Figure 2c). 40 The hydrogel layer chemically bonded on the Zn metal surface possesses an anticatalysis effect, which effectively suppresses both the hydrogen evolution reaction and dendrite formation. As a result, stable and reversible Zn stripping/plating over 1000 h can be realized with a rigorous cutoff condition of 10 mA cm −2 /5 mAh cm −2 .…”

Section: Properties Of Smart Batteriesmentioning

confidence: 99%

Hydrogels Enable Future Smart Batteries

Yang

Liu

et al. 2022

ACS Nano

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The growing trend of intelligent devices ranging from wearables and soft robots to artificial intelligence has set a high demand for smart batteries. Hydrogels provide opportunities for smart batteries to self-adjust their functions according to the operation conditions. Despite the progress in hydrogel-based smart batteries, a gap remains between the designable functions of diverse hydrogels and the expected performance of batteries. In this Perspective, we first briefly introduce the fundamentals of hydrogels, including formation, structure, and characteristics of the internal water and ions. Batteries that operate under unusual mechanical and temperature conditions enabled by hydrogels are highlighted. Challenges and opportunities for further development of hydrogels are outlined to propose future research in smart batteries toward all-climate power sources and intelligent wearables.

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Stable Zinc Anodes Enabled by a Zincophilic Polyanionic Hydrogel Layer

Cited by 199 publications

References 68 publications

A Molecular‐Sieve Electrolyte Membrane enables Separator‐Free Zinc Batteries with Ultralong Cycle Life

A Molecular‐Sieve Electrolyte Membrane enables Separator‐Free Zinc Batteries with Ultralong Cycle Life

Triggering Zn²⁺ Unsaturated Hydration Structure via Hydrated Salt Electrolyte for High Voltage and Cycling Stable Rechargeable Aqueous Zn Battery

Hydrogels Enable Future Smart Batteries

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Stable Zinc Anodes Enabled by a Zincophilic Polyanionic Hydrogel Layer

Cited by 199 publications

References 68 publications

A Molecular‐Sieve Electrolyte Membrane enables Separator‐Free Zinc Batteries with Ultralong Cycle Life

A Molecular‐Sieve Electrolyte Membrane enables Separator‐Free Zinc Batteries with Ultralong Cycle Life

Triggering Zn2+ Unsaturated Hydration Structure via Hydrated Salt Electrolyte for High Voltage and Cycling Stable Rechargeable Aqueous Zn Battery

Hydrogels Enable Future Smart Batteries

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Triggering Zn²⁺ Unsaturated Hydration Structure via Hydrated Salt Electrolyte for High Voltage and Cycling Stable Rechargeable Aqueous Zn Battery