Ifra Arshad, Asmat Ullah, Muhammad Khawar Abbas, Shahid Iqbal, Aqeel Ahmad Shah, Asad Akram, Naveed Akhtar Shad, Kh. Abd El-Aziz, Hafiz T. Ali, Yasir Javed
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引用次数: 0
摘要
在本研究中,通过改变Ce浓度为1、2和3%,优化了BiPO4的电化学响应。XRD分析证实制备的BiPO4纳米粒子具有单斜斜结构,空间基团分别为P21/a和P21/m。EDX研究表明掺杂的BiPO4中存在不同浓度的Ce。电化学研究表明,Ce(3%)掺杂的BiPO4在扫描速率为5 mV/s时具有最佳的电化学性能,比电容为784.2 F/g。当b = 0.7时,电极材料的电荷存储性质表现为杂化行为,其中电容性贡献74%,弥漫性贡献26%。基于双电极设置的原型装置在1 a /g时的最大能量密度为24.11 Wh/kg,在7 a /g时的最大能量密度为4900 W/kg, 1000 GCD循环的容量保持率为79.43%。XPS分析表明,Ce (Ce3+和Ce4+)和Bi (Bi3+和Bi5+)存在多种氧化态,这是混合超级电容器中掺杂Ce的BiPO4纳米材料的电化学响应增强的原因。3%掺铈的BiPO4具有增强的电导率和促进电化学氧化还原反应的特性,表明其具有储能应用的潜力。图形抽象
Cerium-modified BiPO4 as a promising electrode material for hybrid supercapacitors
In this research work, the electrochemical response of BiPO4 was optimized by varying the Ce concentration to 1, 2, and 3%. The XRD analysis confirmed the monoclinic structure of the prepared BiPO4 nanoparticles with space group P21/a and P21/m. EDX studies indicated the presence of Ce with different concentrations in the doped BiPO4. The electrochemical investigations showed that Ce (3%)-doped BiPO4 exhibited the best electrochemical properties with a 784.2 F/g of specific capacitance at a scan rate of 5 mV/s. The charge storage nature presented hybrid behavior of the electrode material with b = 0.7, with 74% capacitive and 26% diffusive contributions. The prototype device based on a two-electrode setup presented a maximum energy density of 24.11 Wh/kg at 1 A/g and 4900 W/kg of power density at 7 A/g, with a 79.43% capacity retention for 1000 GCD cycles. The XPS analysis revealed the occurrence of multiple oxidation states of Ce (Ce3+ and Ce4+) and Bi (Bi3+ and Bi5+), responsible for enhanced electrochemical response of Ce-doped BiPO4 nanomaterials for hybrid supercapacitors. The 3% cerium-doped BiPO4 showed enhanced conductivity and facilitated electrochemical redox reactions, indicating its potential for energy storage applications.
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