材料科学
超级电容器
聚丙烯腈
碳化
共聚物
碳纤维
复合材料
电极
增塑剂
电容
化学工程
聚合物
复合数
扫描电子显微镜
化学
物理化学
工程类
作者
Michael Usselmann,Joachim Bansmann,Alexander J. C. Kuehne
标识
DOI:10.1002/adma.202208484
摘要
Abstract Polyacrylonitrile (PAN) represents the most widely used precursor for carbon fibers and carbon materials. Carbon materials stand out with their high mechanical performance, but they also show excellent electrical conductivity and high surface area. These properties render carbon materials suitable as electrode material for fuel cells, batteries, and supercapacitors. However, PAN has to be processed from solution before being thermally converted to carbon, limiting its final format to fibers, films, and non‐wovens. Here, a PAN‐copolymer with an intrinsic plasticizer is presented to reduce the melting temperature and avoid undesired entering of the thermal carbonization regime. This plasticizer enables melt extrusion‐based additive manufacturing (EAM). The plasticizer in the PAN‐copolymer can be switched to increase the melting temperature after processing, allowing the 3D‐melt‐printed workpiece to be thermally carbonized after EAM. Melt‐processing of the PAN copolymer extends the freedom‐in‐design of carbon materials to mold‐free rapid prototyping, in the absence of solvents, which enables more economic and sustainable manufacturing processes. As an example for the capability of this material system, open meshed carbon electrodes are printed for supercapacitors that are metal‐ and binder‐free with an optimized thickness of 1.5 mm and a capacitance of up to 387 mF cm −2 .
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