Tahani Mazyad Almutairi, Mehar Un Nisa, Sana Ijaz, Abdul Ghafoor Abid, Syed Imran Abbas Shah, Muhammad Fahad Ehsan
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引用次数: 0
摘要
一种简单的一步水热工艺被用于开发一种有利的材料,用于超级电容器等储能设备。使用最先进的技术,以及电化学参数,包括恒流充放电、电化学阻抗谱和循环伏安法,对电极材料进行表征,以研究能量存储行为,如比电容(Csp)、功率密度和能量密度。可扩展的Bi2S3纳米棒沉积在蛋壳膜电极(ESMEs)上,在1 a /g下显示出更高的Csp,为580.61 F/g。计算得到的能量密度分别为29.3、22.7、18.8和15.0 W h/kg,而在1、2、5和10 A/g条件下的功率密度分别为263.1、349.3、663.1和870.0 W/kg。这些令人印象深刻的结论归因于Bi2S3/ESME的电活性表面积(625 cm2)的增强。这些材料的独特结构,具有可观的表面积(78.3 cm2/g),有助于提高性能。这项研究的发现可以为提高未来应用程序的性能提供新的策略。
Bi2S3 nanorods supported on eggshell membrane electrodes for supercapacitor applications
A simple one-step hydrothermal process was employed to develop a favorable class of materials toward energy storage devices such as supercapacitors. The electrode material was characterized using state-of-the-art techniques, along with electrochemical parameters, including galvanostatic charge–discharge, electrochemical impedance spectroscopy, and cyclic voltammetry, toward investigate energy storage behaviors, such as specific capacitance (Csp), power density, and energy density. Scalable Bi2S3 nanorods deposited on eggshell membrane electrodes (ESMEs) exhibit a much greater Csp of 580.61 F/g on 1 A/g. Calculated energy densities are 29.3, 22.7, 18.8, and 15.0 W h/kg, whereas the power densities are 263.1, 349.3, 663.1, and 870.0 W/kg at 1, 2, 5, and with 10 A/g, respectively. These impressive conclusions are attributed to the enhanced electroactive surface area of Bi2S3/ESME (625 cm2). The unique structure of these materials, featuring a substantial surface area (78.3 cm2/g), contributes to this enhanced performance. The findings of this study could inform new strategies for boosting the performance of future applications.
期刊介绍:
The International Journal of Applied Ceramic Technology publishes cutting edge applied research and development work focused on commercialization of engineered ceramics, products and processes. The publication also explores the barriers to commercialization, design and testing, environmental health issues, international standardization activities, databases, and cost models. Designed to get high quality information to end-users quickly, the peer process is led by an editorial board of experts from industry, government, and universities. Each issue focuses on a high-interest, high-impact topic plus includes a range of papers detailing applications of ceramics. Papers on all aspects of applied ceramics are welcome including those in the following areas:
Nanotechnology applications;
Ceramic Armor;
Ceramic and Technology for Energy Applications (e.g., Fuel Cells, Batteries, Solar, Thermoelectric, and HT Superconductors);
Ceramic Matrix Composites;
Functional Materials;
Thermal and Environmental Barrier Coatings;
Bioceramic Applications;
Green Manufacturing;
Ceramic Processing;
Glass Technology;
Fiber optics;
Ceramics in Environmental Applications;
Ceramics in Electronic, Photonic and Magnetic Applications;
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