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Insights into the carbonization mechanism of PAN-derived carbon precursor fibers and establishment of a kinetics-driven accelerated reaction template for atomistic simulation

Pengcheng Shi, Yingdan Zhu, Hai‐Bing Xu, Chun Yan, Dong Liu, Lingyu Yue, Gang Chen

2023Physical Chemistry Chemical Physics10 citationsDOI

Abstract

/tar vapor) formation and a pragmatic kinetics-driven accelerated reaction template for atomistic simulation of the carbonization process overcoming traditional challenges in time scale discrepancy of the reaction-diffusion system. The results of enthalpy barriers from hybrid first principles calculations validate the rationality and sequence of conjectured reactions during the two-stage carbonization process. Conversion rates of the rate-determining steps under 300 s carbonization are also estimated based on Eyring's transition state theory realizing kinetics equivalency of the reaction extent. Process-control measurements are further demonstrated corresponding to the proposed mechanism. The iterative densified crosslinking scheme specially designed for the surface layer is implanted into the topological reaction molecular dynamics template and a series of highly devisable structural models during the whole evolutionary process from the pre-oxidized fiber to the pristine carbon fiber surface are successfully predicted. The ultimate structure of the model presents excellent similarity in carbon yield and elemental composition with the type II high strength carbon fiber surface.

Topics & Concepts

CarbonizationMaterials sciencePolyacrylonitrileCarbon fibersTransition state theoryChemical kineticsKineticsNanotechnologyChemical engineeringComposite materialPolymerReaction rate constantQuantum mechanicsScanning electron microscopePhysicsEngineeringComposite numberFiber-reinforced polymer compositesGraphene research and applicationsPolymer crystallization and properties
Insights into the carbonization mechanism of PAN-derived carbon precursor fibers and establishment of a kinetics-driven accelerated reaction template for atomistic simulation | Litcius