Experimental and theoretical insights into benzene-1,4-dicarboxylic acid based Co-MOFs: an anodic material for expedient battery-supercapacitor hybrids†

IF 5 3区 材料科学 Q2 CHEMISTRY, PHYSICAL
Junaid Khan, Anique Ahmed, Muhammad Imran Saleem and Abdullah A. Al-Kahtani
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Abstract

Hybrid supercapacitors, integrating both faradaic and non-faradaic mechanisms, have emerged as promising energy storage devices owing to their high energy density and excellent cycling stability. In the pursuit of sustainable energy storage solutions, the development of advanced materials has garnered significant attention. Herein, we report benzene-1,4-dicarboxylic acid-based cobalt metal-organic frameworks (Co-MOFs) for application in battery supercapacitor hybrid configuration. The Co-MOFs were synthesized via a simple and scalable hydrothermal method, resulting in a mixed nanoflower structure. The electrochemical setup of a bare electrode uncovers its marvelous advantages with a specific capacity of 500.80 C g−1 (3 mV s−1) and 411.13 C g−1 (1.0 A g−1). A predominant diffusive nature of the Co-MOFs (89.11% at 3 mV s−1) was revealed via a simulation approach that back these merits. Furthermore, an asymmetric supercapacitor assembled with the Co-MOFs and activated carbon exhibited high specific capacity (254.45 C g−1), along with outstanding specific energy and power (60.07 W h kg−1 and 850 W kg−1, respectively). Besides, satisfactory rate capability (retains 58.47% of its specific capacity and energy while boosting specific power by 6 times) and a stable cycling life were observed. The simulation of experimental outcomes revealed the hybrid nature of the device with 80.01% diffusive and 76.72% capacitive contribution at 3 and 100 mV s−1, respectively. The findings unveil the Co-MOFs as an excellently tailored and eco-conscious choice for electrode materials in advanced energy storage devices, driving advancements in sustainable energy technologies.

Abstract Image

基于苯-1,4-二羧酸的 Co-MOFs 的实验和理论研究:一种用于电池和超级电容器混合材料的阳极材料†。
混合超级电容器融合了法拉第和非法拉第两种机制,具有高能量密度和出色的循环稳定性,已成为前景广阔的储能设备。在追求可持续储能解决方案的过程中,先进材料的开发备受关注。在此,我们报告了苯-1,4-二羧酸基钴金属有机框架(Co-MOFs)在电池超级电容器混合配置中的应用。Co-MOFs 是通过一种简单且可扩展的水热法合成的,形成了一种混合纳米花结构。裸电极的电化学设置揭示了其惊人的优势,比容量为 500.80 C g-1(3 mV s-1)和 411.13 C g-1(1.0 A g-1)。通过一种支持这些优点的模拟方法,发现了 Co-MOFs 的主要扩散特性(3 mV s-1 时为 89.11%)。此外,用 Co-MOFs 和活性炭组装的不对称超级电容器显示出很高的比容量(254.45 C g-1),以及出色的比能量和比功率(分别为 60.07 W h kg-1 和 850 W kg-1)。此外,还观察到了令人满意的速率能力(保留了 58.47% 的比容量和能量,同时比功率提高了 6 倍)和稳定的循环寿命。对实验结果的模拟揭示了该器件的混合性质,在 3 mV s-1 和 100 mV s-1 时,扩散贡献率分别为 80.01%,电容贡献率为 76.72%。研究结果表明,Co-MOFs 是先进储能设备电极材料中一种极佳的定制和环保选择,可推动可持续能源技术的进步。
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来源期刊
Sustainable Energy & Fuels
Sustainable Energy & Fuels Energy-Energy Engineering and Power Technology
CiteScore
10.00
自引率
3.60%
发文量
394
期刊介绍: Sustainable Energy & Fuels will publish research that contributes to the development of sustainable energy technologies with a particular emphasis on new and next-generation technologies.
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