Impacts of Mn Content and Mass Loading on the Performance of Flexible Asymmetric Solid-State Supercapacitors Using Mixed-Phase MnO2/N-Containing Graphene Composites as Cathode Materials

C Pub Date : 2023-09-10 DOI:10.3390/c9030088

Hsin-Ya Chiu, Chun-Pei Cho

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Abstract

MnO2/nitrogen-containing graphene (x-NGM) composites with varying contents of Mn were used as the electrode materials for flexible asymmetric solid-state supercapacitors. The MnO2 was a two-phase mixture of γ- and α-MnO2. The combination of nitrogen-containing graphene and MnO2 improved reversible Faraday reactions and charge transfer. However, excessive MnO2 reduced conductivity, hindering ion diffusion and charge transfer. Overloading the electrode with active materials also negatively affected conductivity. Both the mass loading and MnO2 content were crucial to electrochemical performance. x-NGM composites served as cathode materials, while graphene acted as the anode material. Operating by two charge storage mechanisms enabled a synergistic effect, resulting in better charge storage purposes. Among the supercapacitors, the 3-NGM1//G1 exhibited the highest conductivity, efficient charge transfer, and superior capacitive characteristics. It showed a superior specific capacitance of 579 F·g−1, leading to high energy density and power density. Flexible solid-state supercapacitors using x-NGM composites demonstrated good cycle stability, with a high capacitance retention rate of 86.7% after 2000 bending cycles.

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锰含量和质量载荷对含锰/氮混合相石墨烯复合材料柔性非对称固态超级电容器性能的影响

采用不同Mn含量的MnO2/含氮石墨烯(x-NGM)复合材料作为柔性非对称固态超级电容器的电极材料。MnO2为γ-和α-MnO2的两相混合物。含氮石墨烯和二氧化锰的结合改善了可逆法拉第反应和电荷转移。然而，过量的MnO2降低了电导率，阻碍了离子扩散和电荷转移。用活性物质使电极过载也会对电导率产生负面影响。质量负载和MnO2含量对电化学性能至关重要。x-NGM复合材料作为正极材料，石墨烯作为负极材料。通过两种电荷存储机制的操作，实现了协同效应，从而达到更好的电荷存储目的。在超级电容器中，3-NGM1//G1具有最高的电导率、高效的电荷转移和优异的电容特性。该材料具有579 F·g−1的优越比电容，具有较高的能量密度和功率密度。采用x-NGM复合材料制备的柔性固态超级电容器具有良好的循环稳定性，在2000次弯曲循环后，其电容保持率高达86.7%。

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