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Carbon fiber epoxy‐matrix composites with hydrothermal‐carbon‐coated halloysite nanotube filler exhibiting enhanced strength and thermal conductivity

Xueping Wu, Junshuai Zhao, Xu Rao, D.D.L. Chung

2020Polymer Composites29 citationsDOI

Abstract

Abstract The incorporation of hydrothermal‐carbon‐coated halloysite clay nanotube (HNT/C) as a filler in continuous carbon fiber polymer‐matrix composite is reported. The HNT/C (0.9 vol% of the fiber composite) with 11.9 vol% carbon enhanced the flexural strength and storage modulus by 18% and 23%, respectively, and decreased the porosity from 4.4% to 0.9%. The strengthening is due to the reduced porosity, effective filler dispersion, and strengthened filler‐matrix bond resulting from the interaction between epoxy and the amine‐functionalized hydrothermal carbon. The filler addition increased the through‐thickness thermal conductivity by 149%. The ductility was unaffected. The glass transition temperature was decreased slightly.

Topics & Concepts

Materials scienceComposite materialCarbon nanotubeFlexural strengthEpoxyHalloysiteFiller (materials)Composite numberThermal conductivityPorosityDuctility (Earth science)Glass transitionHydrothermal circulationPolymerCreepChemical engineeringEngineeringClay minerals and soil interactionsPolymer Nanocomposites and PropertiesGraphene research and applications
Carbon fiber epoxy‐matrix composites with hydrothermal‐carbon‐coated halloysite nanotube filler exhibiting enhanced strength and thermal conductivity | Litcius