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Nanoarchitectured MnO2 Confined to Mesoporous Carbon Microspheres as Bifunctional Electrodes for High-Performance Supercapacitors and Lithium-Ion Capacitors
Industrial & Engineering Chemistry Research ( IF 3.8 ) Pub Date : 2022-01-19 , DOI: 10.1021/acs.iecr.1c04475 Qizhi Liu 1 , Cheng Ma 1 , Wenming Qiao 1, 2 , Licheng Ling 1, 2 , Jitong Wang 1, 2
Industrial & Engineering Chemistry Research ( IF 3.8 ) Pub Date : 2022-01-19 , DOI: 10.1021/acs.iecr.1c04475 Qizhi Liu 1 , Cheng Ma 1 , Wenming Qiao 1, 2 , Licheng Ling 1, 2 , Jitong Wang 1, 2
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Manganese dioxide (MnO2) is an outstanding electrode material to obtain high pseudocapacitance and specific capacity, but the structure pulverization and poor conductivity during the charge/discharge process are the inevitable problems. Restricting nanoscaled MnO2 in stable pore channels of mesoporous carbon spheres can effectively inhibit its pulverization and obtain an excellent conductive network. Herein, nanoarchitectured MnO2/mesoporous carbon microspheres (MCMs) as bifunctional electrodes for supercapacitors and lithium-ion capacitors (LICs) were prepared through a charily designed facile stratagem containing spray drying and the subsequent redox reaction. The MnO2/MCMs electrode delivers a gravimetric capacitance of 188 F g–1 and a volumetric capacitance of 347 F cm–3 with an outstanding cyclic performance of 90% capacitance retention after 1000 cycles at 1 A g–1, which is ideal for supercapacitors. Moreover, the assembled MnO2/MCMs//activated carbon (AC) lithium-ion capacitors exhibit a long cyclic life of 1300 times with 7.7% capacity loss at 1 A g–1 and a superior energy density of 147 Wh kg–1, as well as a power density of 4952 W kg–1, demonstrating its feasibility on LIC anodes. The excellent electrochemical performance is ascribed to the synergistic effect between MnO2 and mesoporous carbon microspheres, which improves the electrochemical capacities and cyclic stability of both systems. This work provides the possibility for applying bifunctional MnO2/MCMs as electrode materials for high-efficiency hybrid systems.
中文翻译:
限制在介孔碳微球中的纳米结构 MnO2 作为高性能超级电容器和锂离子电容器的双功能电极
二氧化锰(MnO 2)是获得高赝电容和比容量的优秀电极材料,但充放电过程中的结构粉化和导电性差是不可避免的问题。将纳米级MnO 2限制在介孔碳球的稳定孔道中,可以有效抑制其粉化,获得优良的导电网络。在此,通过精心设计的简单策略,包括喷雾干燥和随后的氧化还原反应,制备了纳米结构的 MnO 2 /介孔碳微球 (MCM) 作为超级电容器和锂离子电容器 (LIC) 的双功能电极。MnO 2 /MCMs 电极提供 188 F g 的重量电容–1和 347 F cm –3的体积电容,在 1 A g –1下 1000 次循环后具有出色的循环性能,即 90% 的电容保持率,是超级电容器的理想选择。此外,组装的 MnO 2 /MCMs//活性炭 (AC) 锂离子电容器具有 1300 次的长循环寿命,在 1 A g -1时容量损失为 7.7% ,能量密度高达 147 Wh kg -1,以及 4952 W kg –1的功率密度,证明了其在 LIC 阳极上的可行性。优异的电化学性能归因于 MnO 2之间的协同作用和介孔碳微球,提高了两个系统的电化学容量和循环稳定性。这项工作为将双功能MnO 2 /MCMs用作高效混合系统的电极材料提供了可能性。
更新日期:2022-02-02
中文翻译:
限制在介孔碳微球中的纳米结构 MnO2 作为高性能超级电容器和锂离子电容器的双功能电极
二氧化锰(MnO 2)是获得高赝电容和比容量的优秀电极材料,但充放电过程中的结构粉化和导电性差是不可避免的问题。将纳米级MnO 2限制在介孔碳球的稳定孔道中,可以有效抑制其粉化,获得优良的导电网络。在此,通过精心设计的简单策略,包括喷雾干燥和随后的氧化还原反应,制备了纳米结构的 MnO 2 /介孔碳微球 (MCM) 作为超级电容器和锂离子电容器 (LIC) 的双功能电极。MnO 2 /MCMs 电极提供 188 F g 的重量电容–1和 347 F cm –3的体积电容,在 1 A g –1下 1000 次循环后具有出色的循环性能,即 90% 的电容保持率,是超级电容器的理想选择。此外,组装的 MnO 2 /MCMs//活性炭 (AC) 锂离子电容器具有 1300 次的长循环寿命,在 1 A g -1时容量损失为 7.7% ,能量密度高达 147 Wh kg -1,以及 4952 W kg –1的功率密度,证明了其在 LIC 阳极上的可行性。优异的电化学性能归因于 MnO 2之间的协同作用和介孔碳微球,提高了两个系统的电化学容量和循环稳定性。这项工作为将双功能MnO 2 /MCMs用作高效混合系统的电极材料提供了可能性。
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