Reversible aqueous Zn battery anode enabled by a stable complexation adsorbent interface

Ou, Yangtao; Cai, Zhao; Wang, Jindi; Zhan, Renming; Liu, Shiyu; Lu, Ziheng; Sun, Yongming

doi:10.1002/eom2.12167

Cited by 28 publications

(13 citation statements)

References 41 publications

(63 reference statements)

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“…[3,[31][32][33][34][35] Despite excellent protection effects achieved in the anode/electrolyte interface, the interface thermodynamics stability and ion-transport kinetics are still key and urgent issues, especially at high current densities and extreme temperatures. [36][37][38][39][40] Therefore, a stable interface layer with fast ion transport is highly needed to continuously protect the Zn anode with superior rate capability in wide temperature ranges.…”

Section: Introductionmentioning

confidence: 99%

Semi‐Immobilized Ionic Liquid Regulator with Fast Kinetics toward Highly Stable Zinc Anode under −35 to 60 °C

et al. 2022

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Aqueous zinc ion batteries (ZIBs) have been extensively investigated as a next‐generation energy storage system due to their high safety and low cost. However, the critical issues of irregular dendrite growth and intricate side reactions severely restrict the further industrialization of ZIBs. Here, a strategy to fabricate a semi‐immobilized ionic liquid interface layer is proposed to protect the Zn anode over a wide temperature range from −35 to 60 °C. The immobilized SiO2@cation can form high conjugate racks that can regulate the Zn2+ concentration gradient and self‐polarizing electric field to guarantee uniform nucleation and planar deposition; the free anions of the ILs can weaken the hydrogen bonds of the water to promote rapid Zn2+ desolvation and accelerate ion‐transport kinetics simultaneously. Because of these unique advantages, the cycling performance of the symmetric Zn batteries is greatly enhanced, evidenced by a cycling life of 1800 h at 20 mA cm−2, and a cycle lifespan of 2000 h under a wide temperature window from −35 to 60 °C. The efficiency of this semi‐immobilizing strategy is well demonstrated in various full cells including pouch cells, showing high performance at large current (20 A g−1) and wide temperatures with extra‐long cycles up to 80 000 cycles.

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Section: Introductionmentioning

confidence: 99%

Semi‐Immobilized Ionic Liquid Regulator with Fast Kinetics toward Highly Stable Zinc Anode under −35 to 60 °C

et al. 2022

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“…Many effective strategies were proposed to enable uniform Zn deposition and inhibit side reactions, , such as designing a Zn micromesh to induce spatial-selection deposition, modifying the electrolyte with a cosolvent to change the solvation structure and form a beneficial solid interface, and constructing electrode–electrolyte interphases to protect zinc from parasitic reactions and regulate Zn 2+ deposition. − …”

Section: Introductionmentioning

confidence: 99%

“…These processes, including the undesirable hydrogen evolution, substantially reduce the Coulombic efficiency (CE) of ZIBs. 8 Many effective strategies were proposed to enable uniform Zn deposition and inhibit side reactions, 11,12 such as designing a Zn micromesh to induce spatial-selection deposition, 13 modifying the electrolyte with a cosolvent to change the solvation structure and form a beneficial solid interface, 14 and constructing electrode−electrolyte interphases to protect zinc from parasitic reactions and regulate Zn 2+ deposition. 15−17 Among them, fabricating a protective layer is one of the most effective, simple, and direct methods to prevent Zn from directly contacting the electrolyte and possibly regulate Zn deposition.…”

Section: ■ Introductionmentioning

confidence: 99%

Hybrid Organic/Inorganic Interphase for Stabilizing a Zinc Metal Anode in a Mild Aqueous Electrolyte

Fei

Han

Passerini

et al. 2022

ACS Appl. Mater. Interfaces

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Aqueous rechargeable zinc-based batteries have recently gained tremendous attention because of their low cost and high safety. However, the issues associated with the zinc metal anode, including corrosion, H 2 evolution, and dendrite growth, hinder their practical applications. Herein, we design a hybrid organic/inorganic interphase composed of poly(vinylidene fluoride-cohexafluoropropylene), silica, and zinc triflate to stabilize the zinc metal anode in a mild aqueous electrolyte. It is proven that the artificial interphase reduces corrosion of the Zn metal in the ZnSO 4 electrolyte and suppresses dendrite growth by regulating Zn 2+ deposition. Therefore, the lifespan of symmetrical cells with coated Zn could be enhanced to over 960 h with a stripping/plating capacity of 0.5 mAh cm −2 . In addition, zinc-ion batteries including a sodium vanadate cathode and a coated Zn anode could achieve 3000 cycles with nearly no capacity fading at 5 A g −1 .

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“…6−8 In addition, the Zn dendrite would not only enlarge the volume of the anode but also provide more sites for side reactions and corrosion, resulting into extra consumption of Zn metal and electrolyte. 2,9 Therefore, the approach to alleviate dendrites is the crucial part to accelerate the practical application of large-scale ZMBs. Solid electrolytes are mechanically effective to mitigate dendrite growth.…”

mentioning

confidence: 99%

“…These classic models both confirm that a high current density can accelerate the formation and subsequent growth of dendrites. This problem of uneven Zn plating along with dendrites growth in high-rate Zn metal batteries (ZMBs, a safe and reliable battery for next generation large-scale commercial energy storage system) is also severe and needs to be solved. , The needlelike or sheetlike dendrites can penetrate the separator and result in sudden failure of the battery because of a short circuit. − In addition, the Zn dendrite would not only enlarge the volume of the anode but also provide more sites for side reactions and corrosion, resulting into extra consumption of Zn metal and electrolyte. , Therefore, the approach to alleviate dendrites is the crucial part to accelerate the practical application of large-scale ZMBs. Solid electrolytes are mechanically effective to mitigate dendrite growth .…”

mentioning

confidence: 99%

New Type of Dynamically “Solid–Liquid” Interconvertible Electrolyte for High-Rate Zn Metal Battery

et al. 2022

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The practical application of aqueous high-rate Zn metal battery (ZMB) is limited due to accelerated dendrite formation at high current densities. It is urgent to find an electrolyte, which could not only be mechanically stiff to clamp down dendrites but also not sacrifice ionic conductivity and interfacial compatibility. Herein, a new type of dynamically “solid–liquid” interconvertible electrolyte based on non-Newtonian fluid (NNFE) is proposed. Liquidity characteristic of NNFE is favorable for electrochemical kinetics and interfacial compatibility. Furthermore, in an area with high current rate NNFE would respond and mechanically stiffen to dissuade localized increase in Zn dendrite growth. Even at a current density of 50 mA cm–2, NNFE enables reversible and stable operation of a Zn symmetrical cell over 20 000 cycles. For Zn//Na5V12O32 (NVO) full cell, the NNFE also realizes lengthy cycling for 5000 periods at 5 A g–1. This research opens up new inspirations to high-rate Zn metal even other metal batteries.

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Reversible aqueous Zn battery anode enabled by a stable complexation adsorbent interface

Cited by 28 publications

References 41 publications

Semi‐Immobilized Ionic Liquid Regulator with Fast Kinetics toward Highly Stable Zinc Anode under −35 to 60 °C

Semi‐Immobilized Ionic Liquid Regulator with Fast Kinetics toward Highly Stable Zinc Anode under −35 to 60 °C

Hybrid Organic/Inorganic Interphase for Stabilizing a Zinc Metal Anode in a Mild Aqueous Electrolyte

New Type of Dynamically “Solid–Liquid” Interconvertible Electrolyte for High-Rate Zn Metal Battery

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