Realizing an All‐Round Hydrogel Electrolyte toward Environmentally Adaptive Dendrite‐Free Aqueous Zn–MnO<sub>2</sub> Batteries

Chen, Minfeng; Chen, Jizhang; Zhou, Weijun; Han, Xiang; Yao, Yagang; Wong, Ching‐Ping

doi:10.1002/adma.202007559

Cited by 293 publications

(239 citation statements)

References 68 publications

(34 reference statements)

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“…Furthermore, the constantly occurred side reactions on the Zn anode in aqueous electrolyte impede Zn 2+ transfer, reduce Zn/Zn 2+ reversibility, and exacerbate the Zn dendrite formation problem. [10,11] A lot of endeavor has been made to overcome the above issues, such as employing anti-freezing hydrogel electrolytes, [12][13][14][15] high concentrated "water in salt" electrolytes, [16] modifying the anode interface, [17] and adding electrolyte additives. [18][19][20][21] In these strategies, organic solvents as electrolyte additives have been certified to be low-cost and effective on the subzero temperature application and the dendrite inhibition of Zn-ion batteries.…”

Section: Doi: 101002/smll202103195mentioning

confidence: 99%

Immunizing Aqueous Zn Batteries against Dendrite Formation and Side Reactions at Various Temperatures via Electrolyte Additives

Feng

Cao

Hou

et al. 2021

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Aqueous Zn‐ion batteries own great potential on next generation wearable batteries due to the high safety and low cost. However, the uncontrollable dendrites growth and the negligible subzero temperature performance impede the batteries practical applications. Herein, it is demonstrated that dimethyl sulfoxide (DMSO) is an effective additive in ZnSO4 electrolyte for side reactions and dendrites suppression by regulating the Zn‐ion solvation structure and inducing the Zn2+ to form the more electrochemical stable (002) basal plane, via the higher absorption energy of DMSO with Zn2+ and (002) plane. Moreover, the stable reconstructed hydrogen bonds between DMSO and H2O dramatically lower the freezing point of the electrolyte, which significantly increases the ionic conductivity and cycling performance of the aqueous batteries at subzero temperatures. As a consequence, the symmetrical Zn/Zn cell can be kept stable for more than 2100 h at 20 °C and 1200 h at −20 °C without dendrite and by‐products formation. The Zn/MnO2 batteries can perform steadily for more than 3000 cycles at 20 °C and 300 cycles at −20 °C. This work provides a facile and feasible strategy on designing high performance and dendrite free aqueous Zn‐ion batteries for various temperatures.

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Section: Doi: 101002/smll202103195mentioning

confidence: 99%

Immunizing Aqueous Zn Batteries against Dendrite Formation and Side Reactions at Various Temperatures via Electrolyte Additives

Feng

Cao

Hou

et al. 2021

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231

125

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“…There have been a great number of researches on gel electrolyte with high ion conductivity and adhesion to hamper contact between aqueous solution and Zn anode. Recently, Chen and coworkers fabricated a versatile hydrogel electrolyte for dendrite‐free, noncorrosive, and long‐life AZIBs 66 . The as‐prepared CT3G30 hydrogel composed of cotton as the raw material of polymetric framework and tetraethyl orthosilicate as the crosslinker shows excellent adhesion with Zn electrodes and successfully limits free water molecules to induce side reaction.…”

Section: Issues Solutions and Mechanismsmentioning

confidence: 99%

Issues and rational design of aqueous electrolyte for Zn‐ion batteries

Zhang

Yang

et al. 2021

SusMat

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Aqueous Zn‐ion batteries (AZIBs) are regarded as a promising alternative to the widely used lithium‐ion batteries in large‐scale energy storage systems. The researches on the development of novel aqueous electrolyte to improve battery performance have also attracted great interest since the electrolyte is a key component for Zn2+ migration between cathode and anode. Herein, we briefly summarized and illuminated the recent development tendency of aqueous electrolyte for AZIBs, then deeply analyzed its existing issues (water decomposition, cathode dissolution, corrosion and passivation, and dendrite growth) and discussed the corresponding optimization strategies (pH regulation, concentrated salt solution, electrolyte composition design, and functional additives). The internal mechanisms of these strategies were further revealed and the relationships between issues and solutions were clarified, which could guide the future development of aqueous electrolytes for AZIBs.

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“…[ 1–6 ] Recently, various cathode materials of aqueous Zn batteries have been developed such as Prussian blue analogs, manganese oxides, vanadium‐based compounds, and organic materials. [ 7–16 ] Among these cathode materials, vanadium‐based compounds have attracted great attention due to their open crystal structure and the abundant valence of vanadium. [ 17–20 ] Based on the V 5+ /V 3+ redox couple, V 2 O 5 possesses a superior theoretical capacity of 589 mAh g −1 in comparison with other vanadium‐based compounds.…”

Section: Introductionmentioning

confidence: 99%

A Universal Compensation Strategy to Anchor Polar Organic Molecules in Bilayered Hydrated Vanadates for Promoting Aqueous Zinc‐Ion Storage

et al. 2021

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The electrochemical performance of layered vanadium oxides is often improved by introducing guest species into their interlayer. Guest species with high stability in the interlayer and weak interaction with Zn2+ during charge/discharge process are desired to promoting reversible Zn2+ transfer. Herein, a universal compensation strategy was developed to introduce various polar organic molecules into the interlayer of AlxV2O5·nH2O by replacing partial crystal water. The high‐polar groups in the organic molecules have a strong electrostatic attraction with pre‐intercalated Al3+, which ensures that organic molecules can be anchored in the interlayer of hydrated vanadates. Simultaneously, the low‐polar groups endow organic molecules with a weak interaction with Zn2+ during cycling, thus liberalizing reversible Zn2+ transfer. As a result, AlxV2O5 with polar organic molecules displays enhanced electrochemical performance. Furthermore, based on above cathode material, a pouch cell was assembled by further integrating a dendrite‐free N‐doped carbon nanofiber@Zn anode, displaying an energy density of 50 Wh kg‐1. This work provides a path for designing stable guest species with a weak interaction with Zn2+ in the interlayer of layered vanadium oxide towards high‐performance cathode materials of aqueous Zn batteries.

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Realizing an All‐Round Hydrogel Electrolyte toward Environmentally Adaptive Dendrite‐Free Aqueous Zn–MnO₂ Batteries

Cited by 293 publications

References 68 publications

Immunizing Aqueous Zn Batteries against Dendrite Formation and Side Reactions at Various Temperatures via Electrolyte Additives

Immunizing Aqueous Zn Batteries against Dendrite Formation and Side Reactions at Various Temperatures via Electrolyte Additives

Issues and rational design of aqueous electrolyte for Zn‐ion batteries

A Universal Compensation Strategy to Anchor Polar Organic Molecules in Bilayered Hydrated Vanadates for Promoting Aqueous Zinc‐Ion Storage

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Realizing an All‐Round Hydrogel Electrolyte toward Environmentally Adaptive Dendrite‐Free Aqueous Zn–MnO2 Batteries

Cited by 293 publications

References 68 publications

Immunizing Aqueous Zn Batteries against Dendrite Formation and Side Reactions at Various Temperatures via Electrolyte Additives

Immunizing Aqueous Zn Batteries against Dendrite Formation and Side Reactions at Various Temperatures via Electrolyte Additives

Issues and rational design of aqueous electrolyte for Zn‐ion batteries

A Universal Compensation Strategy to Anchor Polar Organic Molecules in Bilayered Hydrated Vanadates for Promoting Aqueous Zinc‐Ion Storage

Contact Info

Product

Resources

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Realizing an All‐Round Hydrogel Electrolyte toward Environmentally Adaptive Dendrite‐Free Aqueous Zn–MnO₂ Batteries