PPY/RGO/CoNd-LDH超级电容器电极材料的制备与电化学性能
Preparation and Electrochemical Properties of PPY/RGO/CoNd-LDH Supercapacitor Electrode Materials
DOI: 10.12677/HJCET.2023.136048, PDF,    科研立项经费支持
作者: 田 宇*, 王 静#, 张 磊, 陈 啸, 尚晨伟:安徽理工大学材料科学与工程学院,安徽 淮南;李育飞, 徐立新:浙江工业大学平湖新材料研究院,浙江 平湖
关键词: 石墨烯聚吡咯层状双金属氢氧化物电化学性能超级电容器Graphene Polypyrrole Layered Bimetallic Hydroxide Electrochemical Properties Supercapacitor
摘要: 利用rGO、PPY和CoNd-LDH三种材料,采取原位聚合法,制备PPY、PPY/rGO、PPY/CoNd-LDH、PPY/rGO/CoNd-LDH等新型复合材料。借助扫描电镜、X射线衍射分析、红外光谱和电化学分析等表征测试手段,分析材料的形貌、微观结构和电学性能。结果表明三元复合物电流密度1 A/g时的比电容达到594 F/g,相比纯PPY比电容提升184.2%,相比PPY/RGO,PPY/CoNd-LDH二元复合碳材料比电容提升74.7%和28%,并具有良好的循环稳定性。结果表明,PPY/RGO/CoNd-LDH复合材料是很有前途的超级电容器电极材料。
Abstract: Three materials, rGO, PPY and CoNd-LDH, were used to prepare new composites such as PPY, PPY/rGO, PPY/CoNd-LDH and PPY/rGO/CoNd-LDH by in situ polymerization method. The morphology, microstructure and electrical properties of the materials were analyzed by means of characterization tests such as scanning electron microscopy, X-ray diffraction analysis, infrared spectroscopy and electrochemical analysis. The results show that the specific capacitance of the ternary complexes reaches 594 F/g at a current density of 1 A/g, which is 184.2% higher than that of pure PPY, 74.7% higher than that of PPY/RGO, and 28% higher than that of PPY/CoNd-LDH binary composite carbon materials, and has good cycling stability. The results indicate that PPY/ RGO/CoNd-LDH composites are promising electrode materials for supercapacitors.
文章引用:田宇, 王静, 张磊, 陈啸, 尚晨伟, 李育飞, 徐立新. PPY/RGO/CoNd-LDH超级电容器电极材料的制备与电化学性能[J]. 化学工程与技术, 2023, 13(6): 418-429. https://doi.org/10.12677/HJCET.2023.136048

参考文献

[1] Wang, G., Zhang, L. and Zhang, J. (2012) A Review of Electrode Materials for Electrochemical Supercapacitors. Chemical Society Reviews, 41, 797-828. [Google Scholar] [CrossRef
[2] Scibioh, M.A. and Viswanathan, B. (2020) Supercapacitor: An Introduction. In: Scibioh, M.A. and Viswanathan, B., Eds., Materials for Supercapacitor Applications, Elsevier, Amsterdam, 1-13. [Google Scholar] [CrossRef
[3] Li, K.S., Lu, X.Y., Zhang, Y., Liu, K.L., Huang, Y.C. and Liu, H. (2020) Bi3TaO7/Ti3C2 Heterojunctions for Enhanced Photocatalytic Removal of Water-Borne Contaminants. Environmental Research, 185, Article ID: 109409. [Google Scholar] [CrossRef] [PubMed]
[4] Kim, E., Kim, S., Choi, Y.M., et al. (2020) Ultrathin Hem-atite on Mesoporous WO3 from Atomic Layer Deposition for Minimal Charge Recombination. ACS Sustainable Chemistry & Engineering, 8, 11358-11367. [Google Scholar] [CrossRef
[5] González, A., Goikolea, E., Barrena, J.A. and Mysyk, R. (2016) Review on Supercapacitors: Technologies and Materials. Renewable and Sustainable Energy Reviews, 58, 1189-1206. [Google Scholar] [CrossRef
[6] Najib, S. and Erdem, E. (2019) Current Progress Achieved in Novel Materials for Supercapacitor Electrodes: Mini Review. Nanoscale Advances, 1, 2817-2827. [Google Scholar] [CrossRef
[7] Xin, L. and Wei, B. (2012) Supercapacitors Based on Nanostruc-tured Carbon. Nano Energy, 2, 159-173. [Google Scholar] [CrossRef
[8] Huang, Y., Yang, H., Xiong, T., et al. (2019) Adsorption Energy Engineering of Nickel Oxide Hybrid Nanosheets for High Areal Capacity Flexible Lithium-Ion Batteries. Energy Storage Materials, 25, 41-51. [Google Scholar] [CrossRef
[9] Xiong, T., Su, H., Yang, F., et al. (2020) Harmonizing Self-Supportive VN/MoS2 Pseudocapacitance Core-Shell Electrodes for Boosting the Areal Capacity of Lithium Storage. Materials Today Energy, 17, Article ID: 100461. [Google Scholar] [CrossRef
[10] Dai, J., Fu, K., Palanisamy, R., et al. (2017) A Solid State Energy Storage Device with Supercapacitor—Battery Hybrid Design. Journal of Materials Chemistry A, 5, 15266-15272. [Google Scholar] [CrossRef
[11] Dubal, D.P., Ayyad, O., Ruiz, V. and Gómez-Romero, P. (2015) Hybrid Energy Storage: The Merging of Battery and Supercapacitor Chemistries. Chemical Society Reviews, 44, 1777-1790. [Google Scholar] [CrossRef
[12] Beguin, F., Presser, V. and Balducci, A. (2014) Carbons and Electrolytes for Advanced Supercapacitors. Advanced Materials, 26, 2219-2251. [Google Scholar] [CrossRef] [PubMed]
[13] Choudhary, N., Li, C., Moore, J., et al. (2017) Asymmetric Supercapacitor Electrodes and Devices. Advanced Materials, 29, Article ID: 1605336. [Google Scholar] [CrossRef] [PubMed]
[14] Borenstein, A., Hanna, O., Ran, A., et al. (2017) Carbon-Based Composite Materials for Supercapacitor Electrodes: A Review. Journal of Materials Chemistry A, 5, 12653-12672. [Google Scholar] [CrossRef
[15] Wang, Q.F., Ma, Y., Liang, X., Zhang, D.H. and Miao, M.H. (2018) Novel Core/Shell CoSe2 @PPY Nanoflowers for High Performance Fiber Asymmetric Supercapacitors. Journal of Materials Chemistry A, 6, 10361-10369. [Google Scholar] [CrossRef
[16] Sharma, P. and Kumar, V. (2020) Current Technology of Super-capacitors: A Review. Journal of Electronic Materials, 49, 3520-3532. [Google Scholar] [CrossRef
[17] 李雪芹, 常琳, 赵慎龙, 等. 基于碳材料的超级电容器电极材料的研究[J]. 物理化学学报, 2017, 33(1): 130-148.
[18] Winter, M. and Brodd, R.J. (2004) What Are Bat-teries, Fuel Cells, and Supercapacitors. Chemical Reviews, 104, 4245-4270. [Google Scholar] [CrossRef] [PubMed]
[19] 孙光林. 含氮碳及碳基@纳米金属化合物超级电容器材料的制备与应用研究[D]: [博士学位论文]. 武汉: 武汉大学, 2017.
[20] Schoetz, T., Kurniawan, M., Stich, M., et al. (2018) Understanding the Charge Storage Mechanism of Conductive Polymers as Hybrid Battery-Capacitor Materials in Ionic Liquids by in situ Atomic Force Microscopy and Electrochemical Quartz Crystal Microbalance Studies. Journal of Materials Chemistry A, 6, 17787-17799. [Google Scholar] [CrossRef
[21] Dong, L., Yang, W., Yang, W., et al. (2019) Multivalent Metal Ion Hybrid Capacitors: A Review with a Focus on Zinc-Ion Hybrid Capacitors. Journal of Materials Chemistry A, 7, 13810-13832. [Google Scholar] [CrossRef
[22] Xu, X., Ray, R., Gu, Y., et al. (2004) Electrophoretic Analysis and Purification of Fluorescent Single-Walled Carbon Nanotube Fragments. Journal of the American Chemical Society, 126, 12736-12737. [Google Scholar] [CrossRef] [PubMed]
[23] Molaei, M.J. (2020) The Optical Properties and Solar Energy Conversion Applications of Carbon Quantum Dots: A Review. Solar Energy, 196, 549-566. [Google Scholar] [CrossRef
[24] Janus, Ł., Radwan-Pragłowska, J., Piątkowski, M. and Bogdał, D. (2020) Facile Synthesis of Surface-Modified Carbon Quantum Dots (CQDs) for Biosensing and Bioimaging. Materials, 13, Article 3313. [Google Scholar] [CrossRef] [PubMed]
[25] 王信, 黄润青, 牛树章, 等. 石墨烯基材料在高性能锂金属电池中的研究进展[J]. 新型炭材料, 2021, 36(4): 711-728.
[26] Lee, C., Wei, X., Kysar, J.W. and Hone, J. (2008) Measurement of the Elastic Properties and Intrinsic Strength of Monolayer Graphene. Science, 321, 385-388. [Google Scholar] [CrossRef] [PubMed]
[27] Huang, J., Zhao, X., Huang, H., et al. (2019) Scalable Production of Few Layered Graphene by Soft Ball-Microsphere Rolling Transfer. Carbon, 154, 402-409. [Google Scholar] [CrossRef
[28] Jaafar, E., Kashif, M., Sahari, S.K. and Ngaini, Z. (2018) Study on Morphological, Optical and Electrical Properties of Graphene Oxide (GO) and Reduced Graphene Oxide (rGO). Materials Science Forum, 917, 112-116. [Google Scholar] [CrossRef
[29] Wang, Y., Yang, W. and Yang, J. (2007) A Co-Al Layered Double Hydroxides Nanosheets Thin-Film Electrode: Fabrication and Electrochemical Study. Elec-trochemical and Solid State Letters, 10, A233-A236. [Google Scholar] [CrossRef
[30] Wang, Y., Hu, X., Li, W., et al. (2020) Preparation of Boron Nitrogen Co-Doped Carbon Quantum Dots for Rapid Detection of Cr(VI). Spectrochimica Acta Part A: Molecular and Bi-omolecular Spectroscopy, 243, Article ID: 118807. [Google Scholar] [CrossRef] [PubMed]
[31] Wang, Y., Zhuang, Q.F. and Ni, Y.N. (2015) Facile Micro-wave-Assisted Solid-Phase Synthesis of Highly Fluorescent Nitrogen-Sulfur-Codoped Carbon Quantum Dots for Cellular Imaging Applications. Chemistry—A European Journal, 21, 13004-13011. [Google Scholar] [CrossRef] [PubMed]
[32] Sahu, S., Behera, B., Maiti, T.K. and Mohapatra, S. (2012) Simple One-Step Synthesis of Highly Luminescent Carbon Dots from Orange Juice: Application as Excellent Bio-Imaging Agents. Chemical Communications, 48, 8835-8837. [Google Scholar] [CrossRef] [PubMed]
[33] Mehta, V.N., Jha, S. and Kailasa, S.K. (2014) One-Pot Green Syn-thesis of Carbon Dots by Using Saccharum officinarum Juice for Fluorescent Imaging of Bacteria (Escherichia coli) and Yeast (Saccharomyces cerevisiae) Cells. Materials Science & Engineering: C, 38, 20-27. [Google Scholar] [CrossRef] [PubMed]
[34] Zhang, Z., Hao, J., Zhang, J., Zhang, B.L. and Tang, J.L. (2012) Protein as the Source for Synthesizing Fluorescent Carbon Dots by a One-Pot Hydrothermal Route. RSC Advances, 2, 8599-8601. [Google Scholar] [CrossRef
[35] Tang, Q., Zhu, W., He, B. and Yang, P.Z. (2017) Rapid Conversion from Carbohydrates to Large-Scale Carbon Quantum Dots for All-Weather Solar Cells. ACS Nano, 11, 1540-1547. [Google Scholar] [CrossRef] [PubMed]
[36] Fan, G., Wang, H., Xiang, X. and Li, F. (2013) Co-Al Mixed Metal Oxides/Carbon Nanotubes Nanocomposite Prepared via a Precursor Route and En-hanced Catalytic Property. Journal of Solid State Chemistry, 197, 14-22. [Google Scholar] [CrossRef
[37] Ansaldo, A., Bondavalli, P., Bellani, S., et al. (2017) High-Power Graphene—Carbon Nanotube Hybrid Supercapacitors. ChemNanoMat, 3, 436-446. [Google Scholar] [CrossRef
[38] 覃奇贤, 刘淑兰. 电极的极化和极化曲线(I)——电极的极化[J]. 电镀与精饰, 2008, 30(6): 28-30.
[39] Hosseini, M.G. and Shahryari, E. (2016) Synthesis, Characterization and Electrochemical Study of Graphene Oxide-Multi Walled Carbon Nanotube-Manganese Oxide-Polyaniline Electrode as Supercapacitor. Journal of Materials Science & Technology, 32, 763-773. [Google Scholar] [CrossRef
[40] 王文聪. 层状双金属氢氧化物超级电容器电极材料的制备和电化学性能研究[D]: [硕士学位论文]. 杭州: 浙江大学, 2019.
[41] Ajami, N. (2020) PANOA/MnO2/MWCNT Nanocomposite: Synthesis, Characterization, and Electrochemical Performance as Efficient Electrode Materials for Supercapacitors. Journal of Macromolecular Science, Part A, 57, 1-8. [Google Scholar] [CrossRef