Xylan derived carbon sphere/graphene composite film with low resistance for supercapacitor electrode

Journal of Leather Science and Engineering Pub Date : 2024-03-15 DOI:10.1186/s42825-024-00154-w

Jihai Cai, Yujin Li, Rongji Qin, Guangsheng Li, Xiaoying Wang

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Abstract

Reduced graphene oxide (rGO) films suffer from low capacitance for inner unreduced oxygen functional groups, restacking of sheets and high contact resistance. Herein, carbon spheres derived from renewable xylan were added to graphene oxide with large sheet area to fabricate film by gelation and filtration, followed by in situ reduction for high-performance flexible supercapacitor. rGO film with transverse size about 13 μm showed a good specific capacitance of 967 mF/cm² at a scanning rate of 5 mV/s and increased to 1786 mF/cm² by in situ reducing its inner part, which generally remained oxidized due to outer hindering from hydrophobic graphene. Then, by hydrothermal carbonization of xylan and activation with KOH, activated carbon sphere (aXCS) was prepared, which had a diameter of 150–200 nm and a specific capacitance of 270 F/g. The aXCS acted as spacer and connector to avoid restacking of graphene sheets and decrease interlayer contact resistance, resulting 94% increase in capacitance performance from rGO film to aXCS/rGO film. Therefore, combined in situ reduction and enhancement through compositing aXCS, the final film (aXCS/rGO-AA) showed a boosted specific capacitance of 755 mF/cm² at 1 mA/cm² in double electrode system, power density of 22.5–2250 mW/cm², and energy density of 11.88–25.2 mWh/cm². Meanwhile, aXCS/rGO-AA had outstanding cycling stability that its specific capacitance maintained 108.7% after 10,000 cycles of charge–discharge, showing promising potential in wearable and portable electronics.

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用于超级电容器电极的低电阻木聚糖衍生碳球/石墨烯复合膜

还原氧化石墨烯（rGO）薄膜存在内部未还原氧官能团电容低、薄片重新堆积和接触电阻高等问题。横向尺寸约为 13 μm 的 rGO 薄膜在 5 mV/s 的扫描速率下显示出 967 mF/cm2 的良好比电容，并通过原位还原其内部增加到 1786 mF/cm2。然后，通过水热碳化木聚糖并用 KOH 活化，制备出了活性碳球（aXCS），其直径为 150-200 nm，比电容为 270 F/g。aXCS 起到了间隔和连接的作用，避免了石墨烯片的重新堆叠，降低了层间接触电阻，使 rGO 薄膜的电容性能比 aXCS/rGO 薄膜提高了 94%。因此，通过复合 aXCS，结合原位还原和增强，最终薄膜（aXCS/rGO-AA）在双电极系统中 1 mA/cm2 时的比电容提高了 755 mF/cm2，功率密度提高了 22.5-2250 mW/cm2，能量密度提高了 11.88-25.2 mWh/cm2。同时，aXCS/rGO-AA具有出色的循环稳定性，其比电容在充放电10000次循环后仍能保持108.7%，在可穿戴和便携式电子产品中具有广阔的应用前景。

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来源期刊

Journal of Leather Science and Engineering 工程技术-材料科学：综合

CiteScore

12.80

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0.00%

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