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Constructing the Bridge from Isotropic to Anisotropic Pitches for Preparing Pitch-Based Carbon Fibers with Tunable Structures and Properties

Guanming Yuan, Zheng Xue, Zhengwei Cui, Aidan Westwood, Zhijun Dong, Ye Cong, Zhang Jiang, Hui Zhu, Xuanke Li

2020ACS Omega50 citationsDOIOpen Access PDF

Abstract

Synthetic naphthalene pitches (SNPs) with isotropy and anisotropy were prepared by a simple thermal polycondensation method to fabricate pitch-based carbon fibers. The structural characteristic, thermal stability, phase-separation behavior, and melt-spinnability of the SNPs and the structural properties of the derived carbon fibers were systematically investigated. The results show that spinnable SNPs with controllable mesophase contents ranging from 0 to 100 vol % and softening points (210-290 °C) could be easily obtained by a nitrogen-bubbling treatment to improve their thermal stability and melt-spinnability by avoiding the phase separation of liquid crystal (LC) in the pitch. An experimental phase diagram of spinnability and mesophase content is newly proposed for predicting the spinnability of a mesophase-containing pitch. The LC has a significant influence not only on the constituents, structure, and physical properties of the SNPs but also on the final structure and properties of the corresponding pitch-based carbon fibers. The low ash content (less than 0.15 wt %) in the pitch precursor is found to have no obvious effect on the pitch spinnability and the mechanical properties of derivative large-diameter carbon fibers.

Topics & Concepts

MesophaseMaterials scienceComposite materialThermal stabilityLiquid crystalAnisotropyThermosetting polymerCarbon fibersIsotropyPhase (matter)Composite numberChemical engineeringOrganic chemistryPhysicsOptoelectronicsEngineeringChemistryQuantum mechanicsFiber-reinforced polymer compositesMechanical Behavior of CompositesCarbon Nanotubes in Composites
Constructing the Bridge from Isotropic to Anisotropic Pitches for Preparing Pitch-Based Carbon Fibers with Tunable Structures and Properties | Litcius