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Published in:
01-04-2025 | Original Paper
Graphene reinforced UHMWPE fibers
Authors: ZhiJing Xue, Kenneth R. Brown, Timothy M. Harrell, Xiaodong Li
Published in: Journal of Polymer Research | Issue 4/2025
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Abstract
The article investigates the potential of graphene-reinforced ultra-high molecular weight polyethylene (UHMWPE) fibers to revolutionize lightweight, high-performance materials. By leveraging the exceptional properties of graphene, such as superior mechanical strength and thermal conductivity, the study demonstrates significant improvements in the mechanical and thermal performance of UHMWPE fibers. The research employs a gel-spinning method to fabricate graphene/UHMWPE nanocomposite fibers, which are then characterized using advanced techniques like scanning electron microscopy, differential scanning calorimetry, and single-filament tensile testing. The findings reveal that the incorporation of graphene enhances the tensile strength, modulus of elasticity, and crystallinity of the fibers, making them more suitable for high-temperature applications in vehicle construction. Theoretical models are also applied to predict the tensile properties of the composite fibers, providing a comprehensive understanding of the reinforcing effects of graphene. The study highlights the importance of optimizing graphene concentration to achieve the best mechanical and thermal properties, offering valuable insights for the development of advanced composite materials in various industries.
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Abstract
Thermoplastic polymers are increasingly used in electric vehicles, hydrogen fuel cell vehicles, and other decarbonization applications due to their lightweight and formability. Higher-strength polymers are needed to supplant metals in the vehicle structure, thereby reducing mass and improving efficiency. Ultra-high molecular weight polyethylene (UHMWPE) fibers possess one of the highest strength-to-weight ratios of technical polymers, and further improvement via reinforcement by nanofillers, such as graphene, will expand their performance envelope. In this work, UHMWPE/graphene nanocomposite fibers were gel spun and characterized for their morphological, microstructural, thermal, and mechanical properties. The addition of a low fraction of graphene improved the tensile strength of the fibers by 25% and tensile modulus by 32%. Differential scanning calorimetry showed an increase in melting temperature and degree of crystallinity, which indicates improved coordination of the molecular chains induced by the addition of graphene. The reinforcement also affected the cross-sectional shape of the fibers; the aspect ratio of the fibers’ elliptical shape declined with increasing graphene content showing the skeletal effect of the graphene nanofillers in the polymer matrix. The reinforcing effect of graphene declined above a threshold concentration, and theoretical modeling was applied to demonstrate that increased agglomerates led to reduced properties. This work demonstrates a simple, effective method to produce graphene-reinforced UHMWPE fibers and lays a foundation for understanding the potential for leveraging graphene to form ultra-high-performance nanocomposite fibers for myriad engineering applications.
