The Organic Ligand Etching Method for Constructing In Situ Terraced Protective Layer Toward Stable Aqueous Zn Anode

Li, Li; Yang, Hang; Yuan, Zeyu; Tan, Yicheng; Zhang, Yiming; Miao, Chenglin; Chen, Duo; Li, Guangshe; Han, Wei

doi:10.1002/smll.202305554

Cited by 9 publications

(4 citation statements)

References 50 publications

(55 reference statements)

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“…4,5 Rechargeable aqueous metal-ion batteries (RAMB) are considered to be promising large-scale electrochemical energy storage devices. 6 At present, according to the metal ions shuttled in the electrochemical reaction, RAMB can be divided into monovalent (Li + , Na + , and K + ) and multivalent (Zn 2+ , Mg 2+ , and Al 3+ ) ion batteries, 7–15 but most of them exhibit a low energy density due to the low operating voltage. Among them, aqueous zinc-ion batteries (ZIBs) with a mild neutral pH (or slightly acidic) electrolyte and high operating voltage hold particular promise for grid-scale energy storage.…”

Section: Introductionmentioning

confidence: 99%

Open-framework aluminum hexacyanoferrate as a cathode material for high voltage aqueous zinc-ion batteries: effect of Al³⁺ cations on three-phase transition of AlFe(CN)₆

Kong,

Xiao,

Zhang

et al. 2023

Inorg. Chem. Front.

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Section: Introductionmentioning

confidence: 99%

Open-framework aluminum hexacyanoferrate as a cathode material for high voltage aqueous zinc-ion batteries: effect of Al³⁺ cations on three-phase transition of AlFe(CN)₆

Kong,

Xiao,

Zhang

et al. 2023

Inorg. Chem. Front.

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“…1−3 However, the drastic dendrite growth and parasitic side reactions are the main challenges that hinder the application prospects of Zn anodes. 4−6 To stabilize the Zn anode, many strategies have been proposed, including designing 3D electrode structures, 7,8 constructing artificial protective layers, 9,10 and optimizing the electrolyte formula. 11,12 As such, the incorporation of electrolyte additives has been emerged as a facile and efficacious strategy to stabilize the Zn anode.…”

mentioning

confidence: 99%

“…To stabilize the Zn anode, many strategies have been proposed, including designing 3D electrode structures, , constructing artificial protective layers, , and optimizing the electrolyte formula. , As such, the incorporation of electrolyte additives has been emerged as a facile and efficacious strategy to stabilize the Zn anode. Generally, additives can optimize the properties of the anode–electrolyte interface, thereby hindering the undesirable dendrites and side reactions. − For instance, Wang et al introduced dimethyl sulfoxide (DMSO) into ZnCl 2 –H 2 O to regulate the solvation structure of the hydrated Zn 2+ interface and suppress water reduction and Zn dendrite growth .…”

mentioning

confidence: 99%

“…The cycling performance of full cells in various electrolytes is shown in Figure f. At the current density of 1 A g –1 , the Zn||α-MnO 2 full cells using ZnSO 4 electrolytes experienced a drastic capacity attenuation behavior, and the capacity retention is only 5% after 300 cycles due to the drastic short circuit . In sharp contrast, the Zn||α-MnO 2 full cells with the Gly/Asp-containing electrolyte delivered enhanced capacity retention after 300 cycles, further suggesting the positive effect of additives on the cycling stability of the full cells.…”

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confidence: 99%

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Electrolyte Modulation of Biological Chelation Additives toward a Dendrite-Free Zn Metal Anode

Li,

Gou,

Tang

et al. 2023

J. Phys. Chem. Lett.

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Aqueous zinc-ion batteries are considered promising energy storage devices due to their superior electrochemical performance. Nevertheless, the uncontrolled dendrites and parasitic side reactions adversely affect the stability and durability of the Zn anode. To cope with these issues, inspired by the chelation behavior between metal ions and amino acids in the biological system, glutamic acid and aspartic acid are selected as electrolyte additives to stabilize the Zn anode. Experimental characterizations in conjunction with theoretical calculation results indicate that these additives can simultaneously modify the solvation structure of hydrated Zn2+ and preferentially adsorb onto the Zn anode, thereby restricting the occurrence of interfacial side reactions and enhancing the performance of the Zn anode. Benefiting from these synergistic effects, the as-assembled Zn-based batteries containing additive electrolytes achieved admirable electrochemical performance. From the viewpoint of electrolyte regulation, this work provides a bright direction toward the development of aqueous batteries.

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Hydroxylated Manganese Oxide Cathode for Stable Aqueous Zinc‐Ion Batteries

Li,

Liu,

Meng

et al. 2024

Adv Funct Materials

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Manganese (Mn) oxides are promising cathode materials for rechargeable aqueous Zn‐ion batteries. However, the Mn dissolution in weakly acidic electrolytes always hinders the development of better aqueous Zn–Mn batteries. Herein, a hydroxylated manganese oxide cathode material (H‐MnO2) is fabricated using an electrochemical method for stable aqueous Zn–Mn batteries without relying on the Mn2+ electrolyte additives. The partial hydroxylation of the oxides leads to charge redistribution of the material, changing the reaction thermodynamics and kinetics. Theoretical simulation suggests that the hydroxylation of manganese oxide promotes both Zn2+ adsorption thermodynamics and diffusion kinetics on the surface of H‐MnO2 but weakens the interaction between H+ and the electrode. Therefore, Zn2+ ions can be more reactive with the hydroxylated manganese oxide than H+ ions. Experimental results show that the Zn2+ insertion mechanism dominates the charge storage process of H‐MnO2, and the H+‐induced Mn dissolution reaction is effectively alleviated. Importantly, H‐MnO2 exhibits good cycling stability with 95% capacity retention over 5000 cycles at the current density of 3.8 A g−1 in the ZnSO4 electrolyte, outperforming the state‐of‐the‐art aqueous Zn–Mn batteries, even those with Mn2+ electrolyte additives. The findings provide new insights for designing stable manganese oxide cathodes in aqueous Zn–Mn batteries.

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The Organic Ligand Etching Method for Constructing In Situ Terraced Protective Layer Toward Stable Aqueous Zn Anode

Cited by 9 publications

References 50 publications

Open-framework aluminum hexacyanoferrate as a cathode material for high voltage aqueous zinc-ion batteries: effect of Al³⁺ cations on three-phase transition of AlFe(CN)₆

Open-framework aluminum hexacyanoferrate as a cathode material for high voltage aqueous zinc-ion batteries: effect of Al³⁺ cations on three-phase transition of AlFe(CN)₆

Electrolyte Modulation of Biological Chelation Additives toward a Dendrite-Free Zn Metal Anode

Hydroxylated Manganese Oxide Cathode for Stable Aqueous Zinc‐Ion Batteries

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The Organic Ligand Etching Method for Constructing In Situ Terraced Protective Layer Toward Stable Aqueous Zn Anode

Cited by 9 publications

References 50 publications

Open-framework aluminum hexacyanoferrate as a cathode material for high voltage aqueous zinc-ion batteries: effect of Al3+ cations on three-phase transition of AlFe(CN)6

Open-framework aluminum hexacyanoferrate as a cathode material for high voltage aqueous zinc-ion batteries: effect of Al3+ cations on three-phase transition of AlFe(CN)6

Electrolyte Modulation of Biological Chelation Additives toward a Dendrite-Free Zn Metal Anode

Hydroxylated Manganese Oxide Cathode for Stable Aqueous Zinc‐Ion Batteries

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Product

Resources

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Open-framework aluminum hexacyanoferrate as a cathode material for high voltage aqueous zinc-ion batteries: effect of Al³⁺ cations on three-phase transition of AlFe(CN)₆

Open-framework aluminum hexacyanoferrate as a cathode material for high voltage aqueous zinc-ion batteries: effect of Al³⁺ cations on three-phase transition of AlFe(CN)₆