High electrical and thermal conductivities of a PAN-based carbon fiber via boron-assisted catalytic graphitization
- Authors
- Lee, Sora; Cho, Se Youn; Chung, Yong Sik; Choi, Young Chul; Lee, Sungho
- Issue Date
- 2022-10
- Publisher
- Pergamon Press Ltd.
- Citation
- Carbon, v.199, pp.70 - 79
- Abstract
- The boron-assisted catalytic graphitization of carbonaceous materials is an attractive methodology for enhancing their electrical properties by modulating the chemical structures of pristine carbons. In this study, polyacrylonitrile-based carbon fibers (CFs) with highly developed microstructures were prepared by boron -assisted catalytic graphitization. Hydrothermally immersed CFs in boric acid were heat-treated up to 2700 degrees C, and their chemical structures were traced to investigate the boron-assisted catalytic graphitization mechanism. Boron from the gasified boron-related functional groups of CFs diffused into the CFs to form boron carbide, B4C. The boron-substituted CFs exhibited a highly developed crystalline structure that could not be achieved by heat treatment alone, indicating that boron accelerated the graphitic carbon structure. As a result, boron-assisted catalytic graphitization at 2700 degrees C simultaneously enhanced the electrical and thermal conductivities of CFs, with values of 3677.8 S/cm and 365.9 W/mK, respectively, which were 2.8 and 2.4 times higher than those of heat-treated CFs at 2700 degrees C. In addition, CFs were used to prepare CF papers using a wet-laid process, and their heat generation and thermal management capabilities were evaluated. Considering affordable CFs compared to nanomaterials, we believe that our study provides a feasible approach for fabricating heating elements and heat sinks.
- Keywords
- DOPED GRAPHENE; COMPOSITE; POLYACRYLONITRILE; RESISTANCE; MICROSTRUCTURE; NANOSHEETS; NANOTUBES; POLYMER; SENSOR; LAYER; Boron doping; Carbon fiber; Electrical and thermal conductivities; Graphitization; Heating element
- ISSN
- 0008-6223
- URI
- https://pubs.kist.re.kr/handle/201004/114515
- DOI
- 10.1016/j.carbon.2022.07.068
- Appears in Collections:
- KIST Article > 2022
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