| INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
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| A Study on Nickel-Cobalt Nanoflower Composite Materials with P and S Double Vacancies as Supercapacitor Electrodes |
| WU Xuehu, SUN Lixian*, XU Fen*, LI Bin, FANG Songwen, ZHANG Jing, CHEN Xiang, SONG Lingjun, LU Junming, GAO Yuan, DU Maozhan, XU Rudan
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| Guangxi Key Laboratory of Information Materials & Guangxi Collaborative Innovation Center for Structure and Properties for New Energy and Materials, School of Material Science and Engineering, Guilin University of Electronic Technology, Guilin 541004, Guangxi, China |
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Abstract Multinary transition metal oxides and sulfides have garnered intensive interest in the field of supercapacitor electrodes, among which NiCo2S4 has been considered as a hotspot owing to its low cost, low electronegativity and strong electrochemical activity. However, its low electron conductivity and sluggish reaction kinetics have resulted in low specific capacitance, poor rate performance, and rapid capacity decay, limiting its practical applications. Therefore, enhancing the electron conductivity and reaction kinetics of NiCo2S4 is crucial for improving its electrochemical performance. In this study, phosphorus and sulfur co-defected nickel cobalt nanoflowers (P-NiCo2Sn) were synthesized via hydrothermal, sulfidation, and phosphorization methods. During the phosphorization process, both P doping and S vacancy double defects were obtained. These double defects can modulate the electronic structure, generate abundant electrochemical active sites, facilitate electron transfer, and promote reaction dynamics. Moreover, the nanoflower structure has a specific surface area of 66.342 m2·g-1. The P-NiCo2Sn electrode exhibits a specific capacitance of 1 257 F·g-1 at a current density of 1 A·g-1, and an energy density of 44.2 Wh·kg-1 at a power density of 800 W·kg-1. The assembled P-NiCo2Sn//AC asymmetric supercapacitor retains 89.9% of its capacity after 10 000 consecutive charge/discharge cycles.
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Published: 10 April 2025
Online: 2025-04-10
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1 Pang Z H, Qiao Z J, Lei Y W, et al. Materials Reports, 2022, 36(S2), 9 (in Chinese).
庞志恒, 乔志军, 雷贻文, 等. 材料导报, 2022, 36(S2), 9.
2 Zhang Y F. Materials Reports, 2023, 37(S2), 29 (in Chinese).
张亚飞. 材料导报, 2023, 37(S2), 29.
3 Zhang W L, Ran F. Materials Reports, 2020, 34(12), 12010 (in Chinese).
张文林, 冉奋. 材料导报, 2020, 34(12), 12010.
4 Liu R, Xu S, Shao X, et al. ACS Applied Materials & Interfaces, 2021, 13(40), 47717.
5 Sun Y M, Yi R H, Duan J Q, et al. Materials Reports, 2021, 35(16), 16001 (in Chinese).
孙义民, 易荣华, 段纪青, 等. 材料导报, 2021, 35(16), 16001.
6 Chen H, Jiang S, Xu B, et al. Journal of Materials Chemistry A, 2019, 7(11), 6241.
7 Zhao Y H, He X Y, Chen R R, et al. Chemical Engineering Journal, 2018, 352, 29.
8 Yi T F, Pan J J, Wei T T, Nano Today, 2020, 33, 100894.
9 Li L Q, Dai Z Y, Zhang Y F, et al. RSC Advances, 2015, 5(101), 83408.
10 Lu X F, Zhang S L, Gao S Y, et al. Angewandte Chemie, 2021, 133(42), 23067.
11 Peng Z W, Yang C, Hu Y Z, et al. Applied Surface Science A, 2022, 573, 151561.
12 Li L, Song L L, Zhang X Y, et al. ACS Applied Energy Materials, 2022, 5(2), 2505.
13 Lin J H, Wang Y H, Zheng X H, et al. Dalton Transactions, 2018, 47(26), 8771.
14 Tan S W, Xue Z G, Tao K, et al. Chemical Communications, 2022, 58(42), 6243.
15 Salunkhe R R, Tang J, Kamachi Y, et al. Journal of the American Che-mical Society , 2015, 9(6), 6288.
16 Wei X J, Li Y H, Peng Y H, et al. Chemical Engineering Journal, 2019, 355, 336.
17 Lu F, Zhou M, Li W R, et al, Nano Energy, 2016, 26, 313.
18 Zhang X, Lu W, Tian Y H, et al. Journal of Colloid and Interface Science, 2022, 606, 1120.
19 Chen X H, Li Q, Che Q J, et al. ACS Sustainable Chemistry & Engineering, 2019, 7(13), 11778.
20 Yu X W, Zhao J, Johnsson M, et al. Advanced Functional Materials, 2021, 31(25), 2101578.
21 Liang H F, Xia C, Jiang Q, et al. Nano Energy, 2017, 35, 331.
22 Baig M M, Khan M A, Gul I H, et al. Journal of Electronic Materials, 2023, 52, 5775.
23 Wang G R, Jin Z L, Zhang W X. Journal of Colloid and Interface Science, 2020, 577, 115.
24 Mao X Q, Zou Y J, Liang J, et al. Ceramics International, 2020, 46(2), 1448.
25 Zhao Y Y, Zhang P, Fu W B, et al. Applied Surface Science, 2017, 416, 160.
26 Lin J H, Zhong Z X, Wang H H, et al. Journal of Power Sources, 2018, 407, 6.
27 He X Y, Li R M, Liu J Y, et al. Chemical Engineering Journal, 2018, 334, 1573.
28 Su J H, Zhang Y, Lu M, et al. Journal of Alloys and Compounds, 2023, 957, 170387.
29 Li G F, Song B, Cui X, et al. ACS Sustainable Chemistry & Engineering, 2020, 8(3), 1687.
30 Tang J B, Huang W X, Lv X, et al. Nanotechnology, 2020, 32, 085604.
31 Shinde S K, Jalak M B, Ghodake G S, et al. Ceramics International, 2019, 45, 17192.
32 Huang Y X, Cheng M, Xiang Z C, et al. Royal Society Open Science, 2018, 5, 180953.
33 Wang H Y, Liang M M, He Z M, et al. Current Applied Physics, 2022, 35, 7.
34 Liu G X, Zhang H Y, Li J, et al. Journal of Materials Science, 2019, 54, 9666.
35 Yang H Y, Guo R S, Jin L H, et al. Journal of Materials Science:Materials in Electronics, 2023, 34, 2274. |
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2025, Vol. 39 
