Continuous polyimide fiber reinforced ceramic matrix composites with high-temperature flame retardancy and mechanical reliability

doi:10.1016/j.jmst.2025.06.027

Abstract

Abstract: Polyimide fiber (PI_f) based fabric is widely used as a reinforcement in polymer matrix composites for aerospace and automotive applications due to its high specific strength and environmental stability. However, the inadequate flame resistance and high-temperature mechanical properties of polymer matrices limit their performance in fire-prone environments. To address the demand for flame retardancy and mechanical reliability, here we employ ZnO ceramic instead of polymer matrix to prepare continuous PI_f reinforced ceramic matrix composites by using the cold sintering process. The dispersibility of ZnO powder is first optimized by surface modification with a silane coupling agent, which also enhances the flexural strength of cold-sintered ZnO ceramic. After slurry impregnation, the ZnO powder-filled 3D PI_f felt is then densified by cold sintering at a temperature as low as 220 °C. While the ceramic matrix provides the composite with excellent flame retardancy, the polymer fiber improves the thermal shock resistance, which together allow the composite to maintain structural integrity against a 1000 °C flame. Moreover, the composite exhibits extraordinary mechanical reliability and strength with a Weibull modulus of 13.7 and retention of initial strength after 10,000 fatigue cycles at 80 % of fracture stress. The effective load distribution provided by the random PI_f fabric structure, along with the high elongation at break of the PI_f, enables significant energy absorption during crack propagation even under impact damage. This novel ceramic matrix composite expands the application potential of superior performance polymer fibers and establishes a foundation for the development of lightweight, flame-retardant, and mechanically robust materials.

Key words: Polyimide fibers, Ceramic matrix composites, Fatigue resistance, Flame retardancy, Cold sintering process

Jie Min, Xin Zhao, Qi Ding, Peng Yan, Xu Wang, Mingming Si, Yuchi Fan, Wan Jiang. Continuous polyimide fiber reinforced ceramic matrix composites with high-temperature flame retardancy and mechanical reliability[J]. J. Mater. Sci. Technol., 2026, 251: 81-88.

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