Transfiguring energy with an advantageous supercapacitor integrating MoS2/carbon quantum dots bi-composites into a high-performance polypyrrole matrix for unprecedented efficiency

Energy Storage Pub Date : 2024-05-14 DOI:10.1002/est2.632
Rajat Arora, Monika Dhanda, Meena Yadav, Priti Pahuja, Simran Ahlawat, Neeru Jhanjhariya, S. P. Nehra, Suman Lata
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Abstract

For the first time, a simple one-step in situ chemical polymerization technique is used to create a novel molybdenum disulphide/sulphonated carbon quantum dots (CQDs) and polypyrrole (MCP) nanocomposite that is extended for successful use in charge storage supercapacitor (SC) device. By inheriting qualities of excellent electrical conductivity of MoS2, CQDs and improved pseudocapacitive activity of polypyrrole (PPy), the MCP nanocomposite provides a suitable SC electrode material. 0.6 MCP nanocomposited three-electrode system demonstrates 93.21% retention after 5000 cycles, and a maximum specific capacity of 2253 F/g at 2 mV/s with higher side of energy density as 106.06 Wh/kg along with a considerable power density as 180.28 W/kg. Using MCP as anode and an AC or activated charcoal electrode as cathode, a solid-state asymmetric supercapacitor (ASC) was constructed. The fabricated device supplies a greater value of specific capacitance as 154.09 F/g at 100 mV/s and 175 F/g at 0.1 A/g, also evidenced superior energy density data as 126 Wh/kg along with an appreciable power density of 604.8 W/kg. After charging the ASC for 2 min, the light emitting diode shone for 5 min. The findings underpin that MCP is a potential electrode material that could be utilized as a better alternative in futuristic supercapacitor devices.

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将 MoS2/碳量子点双复合材料融入高性能聚吡咯基体的优势超级电容器实现了前所未有的效率,实现了能源转换
该研究首次采用简单的一步原位化学聚合技术制备出新型二硫化钼/磺化碳量子点(CQDs)和聚吡咯(MCP)纳米复合材料,并将其成功应用于电荷存储超级电容器(SC)装置。MCP 纳米复合材料继承了 MoS2 和 CQDs 的优异导电性以及聚吡咯(PPy)的更高伪电容活性,是一种合适的超级电容器电极材料。0.6 MCP 纳米复合三电极系统在 5000 次循环后显示出 93.21% 的保持率,在 2 mV/s 电压下的最大比容量为 2253 F/g,能量密度高达 106.06 Wh/kg,功率密度高达 180.28 W/kg。利用 MCP 作为阳极,交流电或活性炭电极作为阴极,构建了固态非对称超级电容器(ASC)。所制造的装置在 100 mV/s 和 0.1 A/g 条件下分别提供了 154.09 F/g 和 175 F/g 的较大比电容值,还提供了 126 Wh/kg 的卓越能量密度数据和 604.8 W/kg 的可观功率密度。ASC 充电 2 分钟后,发光二极管发光 5 分钟。研究结果表明,MCP 是一种潜在的电极材料,可作为未来超级电容器设备的一种更好的替代材料。
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