基于聚乙烯吡咯烷酮表面活性剂的超级电容器电极材料ZnWO4@rGO的制备及性能研究

doi:10.11896/cldb.25040062

材料导报

2026, Vol. 40

Issue (6): 25040062-8 https://doi.org/10.11896/cldb.25040062

无机非金属及其复合材料

基于聚乙烯吡咯烷酮表面活性剂的超级电容器电极材料ZnWO₄@rGO的制备及性能研究

贺格平^1,*, 傅泽果¹, 杨全^2,*, 鲍晨皓¹, 徐锐¹, 李梦轩¹, 井格格¹, 苟文浩¹

1 西安建筑科技大学材料科学与工程学院,西安 710055;
2 西安建筑科技大学环境与市政工程学院,西安 710055

Preparation and Properties of Supercapacitor Electrode Material ZnWO₄@rGO Based on Polyvinylpyrrolidone Surfactant

HE Geping^1,*, FU Zeguo¹, YANG Quan^2,*, BAO Chenhao¹, XU Rui¹, LI Mengxuan¹, JING Gege¹, GOU Wenhao¹

1 College of Materials Science and Engineering, Xi'an University of Architecture and Technology, Xi'an 710055, China;
2 School of Environmental and Municipal Engineering, Xi'an University of Architecture and Technology, Xi'an 710055, China

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摘要金属氧化物钨酸锌(ZnWO₄)因良好的电化学稳定性和赝电容特性成为超级电容器电极材料的理想选择;还原氧化石墨烯(rGO)兼具独特的二维结构、高比表面积与高载流子迁移率等性能,是制备电极材料的优良添加剂。但是传统石墨烯复合材料因石墨烯分散性较差导致的复合不充分、比容量低、稳定性较差等问题,制约了石墨烯复合电极材料的性能提升。有鉴于此,本工作提供了一种基于非离子表面活性剂辅助制备超级电容器电极ZnWO₄@rGO的方法,即在水热法的基础上,引入聚乙烯吡咯烷酮(PVP)这一非离子型表面活性剂调节与改性ZnWO₄@rGO,利用该方法制备出的ZnWO₄@rGO电极材料的比容量高达1 190 F·g^-1,能量密度为49.9 Wh·kg^-1、1 000次循环后电容保持率为97.4％。这种卓越的性能源于PVP的“导电网络+活性提升+结构稳定+抑制粉化”四重作用机制,进而使得ZnWO₄@rGO的均匀性、结构稳定性和电化学性能得以提升。

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	井格格
	苟文浩

关键词: 还原氧化石墨烯钨酸锌聚乙烯吡咯烷酮(PVP) 水热法超级电容器

Abstract: Metal oxide zinc tungstate(ZnWO₄) is an ideal choice for supercapacitor electrode materials due to its good electrochemical stability and pseudocapacitive properties; meanwhile reduced graphene oxide(rGO) is an excellent additive for the preparation of electrode materials due to its unique two-dimensional structure, high specific surface area, carrier mobility and other unique properties. However, the conventional graphene composites constrain the performance of graphene composite electrode materials due to insufficient composite, low specific capacity, and poor stability caused by poor graphene dispersion. In view of this, the present work provides a method based on nonionic surfactant-assisted preparation of supercapacitor electrode ZnWO₄@rGO, i.e., on the basis of the hydrothermal method, polyvinylpyrrolidone(PVP), a nonionic surfactant, is introduced to regulate and modify the ZnWO₄@rGO, and the ZnWO₄@rGO electrode material prepared using this method has a specific capacity as high as 1 190 F·g^-1, the energy density was 49.9 Wh·kg^-1, and the capacitance retention rate was 97.4% after 1 000 cycles. This excellent performance is attributed to the four-fold mechanism of “conductive network+activity enhancement+structural stabilization+inhibition of chalking” of PVP, which leads to the enhancement of the homogeneity, structural stability, and electrochemical properties of ZnWO₄@rGO.

Key words: reduced graphene oxide zinc tungstate polyvinylpyrrolidone (PVP) hydrothermal method supercapacitor

出版日期: 2026-03-25 发布日期: 2026-04-03

ZTFLH:

TB34

基金资助: 陕西省科技厅重点研发计划(2024GX-YBXM-394);国家大学生创新创业项目(202410703043)

通讯作者: ^*贺格平,西安建筑科技大学材料科学与工程学院副教授、硕士研究生导师。研究方向涵盖纳米材料结构设计、制备、表征及性能研究,超级电容器电极材料及储能研究,纳米结构气敏传感器传感机理研究等领域。hgping2013@126.com
杨全,工学硕士,高级工程师,硕士研究生导师,环境影响评价工程师,从事环境科学与工程教学和环境保护工作。13571800015@163.com

引用本文:

贺格平, 傅泽果, 杨全, 鲍晨皓, 徐锐, 李梦轩, 井格格, 苟文浩. 基于聚乙烯吡咯烷酮表面活性剂的超级电容器电极材料ZnWO₄@rGO的制备及性能研究[J]. 材料导报, 2026, 40(6): 25040062-8.
HE Geping, FU Zeguo, YANG Quan, BAO Chenhao, XU Rui, LI Mengxuan, JING Gege, GOU Wenhao. Preparation and Properties of Supercapacitor Electrode Material ZnWO₄@rGO Based on Polyvinylpyrrolidone Surfactant. Materials Reports, 2026, 40(6): 25040062-8.

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https://www.mater-rep.com/CN/10.11896/cldb.25040062 或 https://www.mater-rep.com/CN/Y2026/V40/I6/25040062

1 Ansari S A, Parveen N, Han T H, et al. Physical Chemistry Chemical Physics, 2016, 18(13), 9053.
2 Tang N, Gao K S, Cao F, et al. Materials Science, 2024, 14(9), 1283(in Chinese).
唐宁, 郜康生, 曹飞, 等. 材料科学, 2024, 14(9), 1283.
3 Guan B, Guo D, Hu L, et al. Journal of Materials Chemistry A, 2014, 2(38), 16116.
4 Liu B T, Shi X M, Lang X Y, et al. Nature Communications, 2018, 9(1), 1375.
5 Chen X, Paul R, Dai L. National Science Review, 2017, 4(3), 453.
6 Wang Guanzhu, Feng Haiman. New Chemical Materials, 2021, 49(11), 267(in Chinese).
王观竹, 冯海满. 化工新型材料, 2021, 49(11), 267.
7 Huang Y W, Wang Y J, Wei S C, et al. Surface Technology, 2018, 47(4), 213(in Chinese).
黄玉炜, 王玉江, 魏世丞, 等. 表面技术, 2018, 47(4), 213.
8 Han Z D, Zhang W Y, Song X N, et al. Chemical Engineering Journal, 2023, 474, 145682.
9 Lyu Z B, Guo E X, Hai Y, et al. Bulletin of the Chinese Ceramic Society, 2022, 41(11), 3979(in Chinese).
吕子彬, 郭恩霞, 海韵, 等. 硅酸盐通报, 2022, 41(11), 3979.
10 M J H, et al. Acta Materiae Compositae Sinica, 2022, 39(10), 4580.
11 Li Y, He G, Huang Z, et al. Journal of Energy Storage, 2024, 101, 113954.
12 Li L, Yue S, Jia S F, et al. The Chemical Record, 2024, 24(4), e202300341.
13 Li Q, Zheng Y C, Wang H N, et al. Science, 2025, 387, 1069.
14 Khayaee A, Rad T S, Nikzat S, et al. Chemical Engineering Journal, 2019, 375, 122102.
15 Trudgeon D P, Qiu K P, Li X H, et al. Journal of Power Sources, 2019, 412, 44.
16 Li X, Wang Y, Zhang Z. Corrosion Science, 2022, 206, 110653.
17 Binglin Guo Yihao Gao Yongyue Li et al. ACS Omega, 2023, 8(7), 6289.
18 Jiang H L, Chen P H, Shu H Y, et al. Experimental Science and Technology, 2018, 16(6), 79(in Chinese).
蒋华麟, 陈萍华, 舒红英, 等. 实验科学与技术, 2018, 16(6), 79.
19 Zhai L L, Zhang J, Li X K, et al. Journal of Inorganic Materials, 2016, 31(6), 588.
20 Hong R Y, Pan T T, Qian J Z, et al. Chemical Engineering Journal, 2006, 119(2), 71.
21 Ji D C, Zhang Z B, Sun J X, et al. ACS Applied Materials & Interfaces, 2024, 16(19), 25304.
22 Yang Y H, Zhu J, Shi W, et al. Materials Letters, 2016, 177, 34.
23 Wu J, Xie R J, Hu X C, et al. Journal of Materials Chemistry A, 2021, 9(15), 9753.
24 Aftab S, Tahir M B, Tahir M S, et al. Journal of Energy Storage, 2022, 56, 106111.
25 Sardar K, Thakur S, Maiti S, et al. Dalton Transactions, 2021, 50(15), 5327.
26 Wang L J, Liu F H, Pal A, et al. Carbon, 2021, 179, 327.

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