Oxygen Defect Engineering And Amphipathic Molecules Intercalation Co-Boosting Fast Kinetics And Stable Structure of S-Doped (Nh 4 ) 2 V 10 O 25 ∙8h 2 O Free-Standing Cathode for Aqueous Zn-Ion Storage

57 Pages Posted: 14 Dec 2023

See all articles by Junye Zhang

Junye Zhang

affiliation not provided to SSRN

Ruona Liu

affiliation not provided to SSRN

Chen Huang

affiliation not provided to SSRN

Ciqing Dong

affiliation not provided to SSRN

Le Xu

affiliation not provided to SSRN

Linying Yuan

Shanghai University

Shigang Lu

Shanghai University

Linlin Wang

Shanghai University

Ling Zhang

University of Shanghai for Science and Technology

Luyang Chen

East China University of Science and Technology

Abstract

The exploration of appropriate layered vanadium-based cathode materials (Zn2+-host) is a crucial and important task for the exploitation of high-performance aqueous zinc ion batteries (AZIBs). Unfortunately, these materials suffer from sluggish kinetics of Zn2+ diffusion and the dissolution of vanadium that make them difficult to reach high capacity and long cycle life. Herein, a novel free-standing cathode (denoted as 3D-NPG@S-NVO@CTAB) has been fabricated by hydrothermal growth of sulfur-doped (NH4)2V10O25∙8H2O (S-NVO) hollow nanoflowers in three-dimensional nitrogen-doped porous graphene (3D-NPG) and subsequent C19H42N+ (CTAB) pre-insertion. Benefitting from the rational design strategy, the oxygen vacancies induced by sulfur doping weaken electrostatic interaction between Zn2+ and cathode, provide more transfer channels and strengthen electronic conductivity. Meanwhile, the simultaneous introduction of S and CTAB into NVO jointly expands interlayer spacing and enhances Zn2+ diffusion kinetics, which suppresses the dissolution of vanadium by reducing water molecule intercalation and maintains the structure integrity with excellent electrochemical performance (525 mAh g-1 at 0.5 A g-1). Even at a high rate of 5 A g-1, the hierarchical cathode (3D-NPG@S-NVO@CTAB) can still deliver a capacity of 356 mAh g-1 with capacity retention rate of 90 % after 2000 cycles. Density functional theory (DFT) calculations indicate that S-doping, the introduction oxygen defects and CTAB obviously strengthen carrier concentration, which represents the enhancement of conductivity. This work can provides ideas for the construction of advanced AZIB devices through the inorganic/organic hybridization of vanadium-based electrode materials.

Keywords: Oxygen vacancies, S-doped, CTAB intercalation, Aqueous zinc ion batteries

Suggested Citation

Zhang, Junye and Liu, Ruona and Huang, Chen and Dong, Ciqing and Xu, Le and Yuan, Linying and Lu, Shigang and Wang, Linlin and Zhang, Ling and Chen, Luyang, Oxygen Defect Engineering And Amphipathic Molecules Intercalation Co-Boosting Fast Kinetics And Stable Structure of S-Doped (Nh 4 ) 2 V 10 O 25 ∙8h 2 O Free-Standing Cathode for Aqueous Zn-Ion Storage. Available at SSRN: https://ssrn.com/abstract=4665201 or http://dx.doi.org/10.2139/ssrn.4665201

Junye Zhang

affiliation not provided to SSRN ( email )

Ruona Liu

affiliation not provided to SSRN ( email )

Chen Huang

affiliation not provided to SSRN ( email )

Ciqing Dong

affiliation not provided to SSRN ( email )

Le Xu

affiliation not provided to SSRN ( email )

Linying Yuan

Shanghai University ( email )

149 Yanchang Road
SHANGDA ROAD 99
Shanghai 200072, 200444
China

Shigang Lu

Shanghai University ( email )

149 Yanchang Road
SHANGDA ROAD 99
Shanghai 200072, 200444
China

Linlin Wang

Shanghai University ( email )

149 Yanchang Road
SHANGDA ROAD 99
Shanghai 200072, 200444
China

Ling Zhang

University of Shanghai for Science and Technology ( email )

Luyang Chen (Contact Author)

East China University of Science and Technology ( email )

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