Frontiers in Energy >

2023 , Vol. 17 >Issue 6: 775 - 781

DOI: https://doi.org/10.1007/s11708-023-0902-8

RESEARCH ARTICLE

Alumina modified sodium vanadate cathode for aqueous zinc-ion batteries

  • Linsong GAN ,
  • Fei LIU ,
  • Xinhai YUAN ,
  • Lijun FU ,
  • Yuping WU
Expand
  • State Key Laboratory of Materials-Oriented Chemical Engineering, School of Energy Science and Engineering, Nanjing Tech University, Nanjing 211816, China
l.fu@njtech.edu.cn (X. YUAN)
xhyuan2022@njtech.edu.cn (L. FU)

Received date: 06 Jul 2023

Accepted date: 21 Sep 2023

Published date: 15 Dec 2023

Copyright

2023 Higher Education Press
Fold

Abstract

Aqueous zinc-ion batteries (ZIBs) have great prospects for widespread application in massive scale energy storage. By virtue of the multivalent state, open frame structure and high theoretical specific capacity, vanadium (V)-based compounds are a kind of the most developmental potential cathode materials for ZIBs. However, the slow kinetics caused by low conductivity and the capacity degradation caused by material dissolution still need to be addressed for large-scale applications. Therefore, sodium vanadate Na2V6O16·3H2O (NVO) was chosen as a model material, and was modified with alumina coating through simple mixing and stirring methods. After Al2O3 coating modification, the rate capability and long-cycle stability of Zn//NVO@Al2O3 battery have been significantly improved. The discharge specific capacity of NVO@Al2O3 reach up to 228 mAh/g (at 4 A/g), with a capacity reservation rate of approximately 68% after 1000 cycles, and the Coulombic efficiency (CE) is close to 100%. As a comparison, the capacity reservation rate of Zn//NVO battery is only 27.7%. Its superior electrochemical performance is mainly attributed to the Al2O3 coating layer, which can increase zinc-ion conductivity of the material surface, and to some extent inhibit the dissolution of NVO, making the structure stable and improving the cyclic stability of the material. This paper offers new prospects for the development of cathode coating materials for ZIBs.

Key words: cathodes; aqueous zinc-ion batteries; sodium vanadate; alumina; coating

Cite this article

Linsong GAN , Fei LIU , Xinhai YUAN , Lijun FU , Yuping WU . Alumina modified sodium vanadate cathode for aqueous zinc-ion batteries[J]. Frontiers in Energy, 2023 , 17(6) : 775 -781 . DOI: 10.1007/s11708-023-0902-8

Acknowledgements

This work was supported by the National Natural Science Foundation of China (Grant Nos. 52122209, 52111530050, 51772147, and 12174270), and the Cultivation Program for “Excellent Doctoral Dissertation” of Nanjing Tech University.

Competing interests

The authors declare that they have no competing interests.

Electronic Supplementary Material

Supplementary material is available in the online version of this article at https://doi.org/10.1007/s11708-023-0902-8 and is accessible for authorized users.

References

Publishing order | Descend order by publishing year | Descend order by cited within
1
Zhu J, Lu L, Zeng K Y. Nanoscale mapping of lithium-ion diffusion in a cathode within an all-solid-state lithium-ion battery by advanced scanning probe microscopy techniques. ACS Nano, 2013, 7(2): 1666–1675

DOI

2
Liu S D, Kang L, Henzie J. . Recent advances and perspectives of battery-type anode materials for potassium ion storage. ACS Nano, 2021, 15(12): 18931–18973

DOI

3
Liu S D, Kang L, Jun S C. Challenges and strategies toward cathode materials for rechargeable potassium-ion batteries. Advanced Materials, 2021, 33(47): 2004689

DOI

4
Dunn B, Kamath H, Tarascon J M. Electrical energy storage for the grid: A battery of choices. Science, 2011, 334(6058): 928–935

DOI

5
Pasta M, Wessells C D, Huggins R A. . A high-rate and long cycle life aqueous electrolyte battery for grid-scale energy storage. Nature Communications, 2012, 3(1): 1149

DOI

6
Qin B, Cai Y F, Wang P C. . Crystalline molybdenum carbide−amorphous molybdenum oxide heterostructures: In situ surface reconfiguration and electronic states modulation for Li–S batteries. Energy Storage Materials, 2022, 47: 345–353

DOI

7
Qin B, Zhao X M, Wang Q. . A tandem electrocatalyst with dense heterointerfaces enabling the stepwise conversion of polysulfide in lithium–sulfur batteries. Energy Storage Materials, 2023, 55: 445–454

DOI

8
Qin B, Cai Y F, Si X Q. . Ultra-lightweight ion-sieving membranes for high-rate lithium sulfur batteries. Chemical Engineering Journal, 2022, 430: 132698

DOI

9
Qin B, Wang Q, Yao W. . Heterostructured Mn3O4-MnS multi-shelled hollow spheres for enhanced polysulfide regulation in lithium–sulfur batteries. Energy & Environmental Materials, 2022, 0: 12475

10
Zhang N, Dong Y, Jia M. . Rechargeable aqueous Zn-V2O5 battery with high energy density and long cycle life. ACS Energy Letters, 2018, 3(6): 1366–1372

DOI

11
Kundu D, Adams B D, Duffort V. . A high-capacity and long-life aqueous rechargeable zinc battery using a metal oxide intercalation cathode. Nature Energy, 2016, 1(10): 16119

DOI

12
He P, Quan Y, Xu X. . High-performance aqueous zinc-ion battery based on layered H2V3O8 nanowire cathode. Small, 2017, 11(47): 17025

13
Bi W, Gao G, Wu G. . Sodium vanadate/PEDOT nanocables rich with oxygen vacancies for high energy conversion efficiency zinc-ion batteries. Energy Storage Materials, 2021, 40: 209–218

DOI

14
Alfaruqi M H, Mathew V, Song J. . Electrochemical zinc intercalation in lithium vanadium oxide: A high-capacity zinc-ion battery cathode. Chemistry of Materials, 2017, 29(4): 1684–1694

DOI

15
He P, Zhang G B, Liao X B. . Sodium ion stabilized vanadium oxide nanowire cathode for high-performance zinc-ion batteries. Advanced Energy Materials, 2018, 8(10): 1702463

DOI

16
Tang B Y, Zhou J, Fang G Z. . Structural modification of V2O5 as high-performance aqueous zinc-ion battery cathode. Journal of the Electrochemical Society, 2019, 166(4): A480–486

DOI

17
Guo X, Fang G Z, Zhang W Y. . Mechanistic insights of Zn2+ storage in sodium vanadates. Advanced Energy Materials, 2018, 8(27): 1801819

DOI

18
Wan F, Niu Z Q. Design strategies for vanadium-based aqueous zinc-ion batteries. Angewandte Chemie International Edition, 2019, 58(46): 16358–16367

DOI

19
Xing Z Y, Xu G F, Han J W. . Facing the capacity fading of vanadium-based zinc-ion batteries. Trends in Chemistry, 2023, 5(5): 380–392

DOI

20
Peng Z, Li Y H, Ruan P C. . Metal-organic frameworks and beyond: The road toward zinc-based batteries. Coordination Chemistry Reviews, 2023, 488: 215190

DOI

21
Yan M, He P, Chen Y. . Water-lubricated intercalation in V2O5·nH2O for high-capacity and high-rate aqueous rechargeable zinc batteries. Advanced Materials, 2018, 30(1): 1703725

DOI

22
Wan F, Zhang L L, Dai X. . Aqueous rechargeable zinc/sodium vanadate batteries with enhanced performance from simultaneous insertion of dual carriers. Nature Communications, 2018, 9(1): 1656

DOI

23
Pang Q, Sun C L, Yu Y H. . H2V3O8 nanowire/graphene electrodes for aqueous rechargeable zinc-ion batteries with high rate capability and large capacity. Advanced Energy Materials, 2018, 8(19): 1800144

DOI

24
Kawabata K, Yoshimatsu H, Fujii E. . Fluidity of a slurry of the graphite powder coated with Al2O3-based metal oxides. Journal of Materials Science Letters, 2001, 20(9): 851–853

DOI

25
Jung Y S, Cavanagh A S, Gedvilas L. . Improved functionality of lithium-ion batteries enabled by atomic layer deposition on the porous microstructure of polymer separators and coating electrodes. Advanced Energy Materials, 2012, 2(8): 1022–1027

DOI

26
Kim D S, Kim Y E, Kim H. Improved fast charging capability of graphite anodes via amorphous Al2O3 coating for high power lithium ion batteries. Journal of Power Sources, 2019, 422: 18–24

DOI

27
Zhang W, Chi Z X, Mao W X. . One-nanometer-precision control of Al2O3 nanoshells through a solution-based synthesis route. Angewandte Chemie International Edition, 2014, 53(47): 12776–12780

DOI

28
Xu Y, Sun D. Structure and catalytic activity of MoZnAlO catalyst for degradation of cationic red GTL under room conditions. Chemical Engineering Journal, 2012, 183: 332–338

DOI

29
Bin D, Huo W C, Yuan Y B. . Organic-inorganic-induced polymer intercalation into layered composites for aqueous zinc-ion battery. Chem, 2020, 6(4): 968–984

DOI

30
Zhu K, Wu T, Huang K. NaCa0.6V6O16·3H2O as an ultra-stable cathode for Zn-ion batteries: The roles of pre-inserted dual-cations and structural water in V3O8 layer. Advanced Energy Materials, 2019, 9(38): 1901968

DOI

31
Zheng J, Liu C, Tian M. . Fast and reversible zinc-ion intercalation in Al-ion modified hydrated vanadate. Nano Energy, 2020, 70: 104519

DOI

32
Wang X K, Zhang X X, Zhao G. . Ether−water hybrid electrolyte contributing to excellent Mg ion storage in layered sodium vanadate. ACS Nano, 2022, 16(4): 6093–6102

DOI

33
Kong L P, Zhang C F, Wang J T. . Free-standing T-Nb2O5/graphene composite papers with ultrahigh gravimetric/volumetric capacitance for Li-ion intercalation pseudocapacitor. ACS Nano, 2015, 9(11): 11200–11208

DOI

34
Wang J, Polleux J, Lim J. . Pseudocapacitive contributions to electrochemical energy storage in TiO2 (anatase) nanoparticles. Journal of Physical Chemistry C, 2007, 111(40): 14925–14931

DOI

35
Liu S D, Kang L, Zhang J. . Structural engineering and surface modification of MOF-derived cobalt-based hybrid nanosheets for flexible solid-state supercapacitors. Energy Storage Materials, 2020, 32: 167–177

DOI

36
Liu S D, Kang L, Zhang J. . Carbonaceous anode materials for non-aqueous sodium- and potassium-ion hybrid capacitors. ACS Energy Letters, 2021, 6(11): 4127–4154

DOI

37
Liu S D, Kang L, Hu J. . Realizing superior redox kinetics of hollow bimetallic sulfide nanoarchitectures by defect-induced manipulation toward flexible solid-state supercapacitors. Small, 2022, 18(5): 2104507

DOI

38
Li X, Li Y, Zhao X. . Elucidating the charge storage mechanism of high-performance vertical graphene cathodes for zinc-ion hybrid supercapacitors. Energy Storage Materials, 2022, 53: 505–513

DOI

39
Dong L B, Yang W, Yang W. . High-power and ultralong-life aqueous zinc-ion hybrid capacitors based on pseudocapacitive charge storage. Nano-Micro Letters, 2019, 11(1): 94

DOI

40
Dang Z Q, Li X, Li Y. . Heteroatom-rich carbon cathodes toward high-performance flexible zinc-ion hybrid supercapacitors. Journal of Colloid and Interface Science, 2023, 644: 221–229

DOI

41
Li Y, Peng X Y, Li X. . Functional ultrathin separators proactively stabilizing zinc anodes for zinc-based energy storage. Advanced Materials, 2023, 35(18): 2300019

DOI

Options
Outlines

/