Accelerated Graphitization of PAN-Based Carbon Fibers: K+-Effected Graphitization via Laser Irradiation

Graphitization progress of polyacrylonitrile (PAN)-based carbon fibers is closely dependent on the treatment temperature; exactly, controlling the microstructural morphology of carbon layers in the fibrous solid state can accelerate the formation of a highly graphitic structure. The present work exhibited the accelerated graphitization of PAN-based carbon fibers by the effect of K+ on microstructure evolution under laser irradiation. Chemical and microstructure characterization reveals that a much higher degree of graphitization is achieved via the K+ effect after the laser irradiation than by pure laser treatment at the same low temperature of about 2000 degrees C. Ordered and large-sized graphite-like microcrystals can be formed as well. The reactive molecular simulation further provided insights into the acceleration mechanism of the K+ effect during the graphitization progress. Thus, based on these results, K+-effected graphitization via laser irradiation can be a promising alternative for the efficient and eco-friendly mass production of graphite fibers.

Automated summary

The graphitization process of PAN-based carbon fibers can be accelerated by the K+ effect, resulting in a higher degree of graphitization and the formation of ordered and large-sized graphite-like microcrystals. Reactive molecular simulation provides insights into the acceleration mechanism of the K+ effect. These results suggest that K+-effected graphitization via laser irradiation can be a promising alternative for the efficient and eco-friendly mass production of graphite fibers.