High-performance nickel oxide–graphene composite as an efficient hybrid supercapacitor

IF 2.2 4区 化学 Q3 CHEMISTRY, MULTIDISCIPLINARY Journal of the Iranian Chemical Society Pub Date : 2024-05-06 DOI:10.1007/s13738-024-03025-7
Seyed Ali Hosseini Moradi, Nader Ghobadi
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Abstract

Supercapacitors, thanks to their unique properties, are considered among the main future energy storage systems. However, problems such as low energy density relative to batteries, spontaneous discharge, and low cell voltage have limited their widespread use. In this regard, the development of active and efficient materials is known as a viable solution. Thus, in this study, a hybrid supercapacitor made of nickel oxide and graphene was investigated. Nickel oxide and graphene were synthesized by calcination of nickel hydroxide and electrochemical exfoliation of graphite, respectively. Nickel oxide–graphene composites were synthesized at three levels, including 10, 20 and 30%wt of graphene by a facile hydrothermal-calcination route. The samples were characterized by XRD, FE-SEM, elemental mapping and FTIR tests, and their electrochemical performance was evaluated by electrochemical measurements including CV and EIS tests. The result of the characterization tests confirmed the successful synthesis of nickel oxide, graphene and composites. The results of the electrochemical measurements also showed that the addition of graphene to nickel oxide improved the supercapacitive properties of pure nickel oxide. Improved performance of the composites was attributed to the less aggregation of graphene sheets and their greater conductivity. Based on the results of electrochemical tests, the optimum level of graphene addition was 20%wt and NiO@G20 supercapacitor in 2.0 M KOH medium and a scan rate of 5 \(\frac{{\text{mV}}}{{\text{s}}}\) showed a specific capacitance of 915.40 \(\frac{{\text{F}}}{{\text{g}}}\), energy density of 31.78 \(\frac{{\text{Wh}}}{{\text{kg}}}\) and power density of 2.29 \(\frac{{\text{kW}}}{{\text{kg}}}\). Also, NiO@G20 supercapacitor was able to maintain 96.7% of its initial capacitance after 5000 cycles, which shows its high cycle stability. The high and stable activity of NiO@G20 introduces it as a promising and high-performance material for supercapacitor.

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作为高效混合超级电容器的高性能氧化镍-石墨烯复合材料
超级电容器因其独特的性能,被认为是未来主要的能源存储系统之一。然而,与电池相比,超级电容器能量密度低、自发放电和电池电压低等问题限制了其广泛应用。在这方面,众所周知,开发活性高效材料是一种可行的解决方案。因此,本研究调查了一种由氧化镍和石墨烯制成的混合超级电容器。氧化镍和石墨烯分别是通过氢氧化镍的煅烧和石墨的电化学剥离合成的。氧化镍-石墨烯复合材料是通过简便的水热-煅烧路线合成的,包括 10%、20% 和 30% 重量的石墨烯。通过 XRD、FE-SEM、元素图谱和傅立叶变换红外测试对样品进行了表征,并通过电化学测量(包括 CV 和 EIS 测试)对其电化学性能进行了评估。表征测试结果证实成功合成了氧化镍、石墨烯和复合材料。电化学测量结果还表明,在氧化镍中添加石墨烯提高了纯氧化镍的超级电容特性。复合材料性能的改善归因于石墨烯薄片的聚集较少以及其导电性更强。根据电化学测试的结果,石墨烯的最佳添加量为 20%wt,NiO@G20 超级电容器在 2.0 M KOH 介质和 5 \(\frac{\{mV}}{\{text{s}})扫描速率下的比电容为 915.40 \(\rac{{text{F}}}{{text{g}}}\),能量密度为 31.78 \(\rac{{text{Wh}}}{{text{kg}}}\),功率密度为 2.29 \(\rac{{text{kW}}}{{text{kg}}}\)。此外,NiO@G20 超级电容器在循环 5000 次后仍能保持其初始电容的 96.7%,这表明它具有很高的循环稳定性。NiO@G20的高活性和稳定性使其成为一种前景广阔的高性能超级电容器材料。
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来源期刊
CiteScore
4.40
自引率
8.30%
发文量
230
审稿时长
5.6 months
期刊介绍: JICS is an international journal covering general fields of chemistry. JICS welcomes high quality original papers in English dealing with experimental, theoretical and applied research related to all branches of chemistry. These include the fields of analytical, inorganic, organic and physical chemistry as well as the chemical biology area. Review articles discussing specific areas of chemistry of current chemical or biological importance are also published. JICS ensures visibility of your research results to a worldwide audience in science. You are kindly invited to submit your manuscript to the Editor-in-Chief or Regional Editor. All contributions in the form of original papers or short communications will be peer reviewed and published free of charge after acceptance.
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