工程技术与管理

多孔芳香框架由于其含氮量高，优异的化学稳定性等优点广泛应用于超级电容器、气体的吸附与分离等方面。在论文中，笔者使用以三聚氯氰和 2,5- 二氨基吡啶二盐酸盐为构筑单元，合成了三嗪基多孔聚合物 TPOP，并制备了不同结构的氮掺杂炭材料，探究了三电极和对称电极超级电容器方面的应用。三电极超级电容器测试表明，炭化温度为 700℃得到的炭产物构建的三电极超级电容器在 0.5 A/g 时比电容达到 195 F/g，远高于聚合物前驱体的电容量。对称超级电容器测试表明，相应炭产物的比电容为 46.9 F/g，能量密度为 16.7 Wh/g，表明该材料在超级电容器中具有良好的应用潜力。

机械研磨法；三嗪基多孔聚合物；超级电容器

Choudhary, N., Li, C., Moore, J., Nagaiah, N., Zhai, L., Jung, Y.,& Thomas, J. (2017). Asymmetric supercapacitor electrodes and devices. Advanced Materials, 29(21), 1605336.

Peng, R., Chen, G., Zhou, F., Man, R., & Huang, J. Catalyst-free synthesis of triazine-based porous organic polymers for Hg2+adsorptive removal from aqueous solution. Chemical Engineering Journal, 2019,371, 260-266.

Kundu, S. K., & Bhaumik, A. A triazine-based porous organic polymer, a novel heterogeneous basic organocatalyst for facile onepot synthesis of 2-amino-4 H-chromenes. RSC Advances,2015,5(41), 32730-32.

Yu, P.; Zhang, Z.; Zheng, L.; Teng, F.; Hu, L.; Fang, X., A novel sustainable flour derived hierarchical nitrogen-doped porous carbon/ polyaniline electrode for advanced asymmetric supercapacitors. Advanced Energy Materials.,2016, 6, 1601111.