@article{Zhang2026, 
author = {Yingpeng Zhang and Zhilin Tian and Bin Li},
title = {Revealing the influence of composition and interface on the mechanical and dielectric properties of Si3N4 fiber-reinforced ceramic composites},
year = {2026},
journal = {Journal of Advanced Ceramics},
keywords = {Interface, Dielectric properties, Ceramic composites, Composition, Si3N4 fibers},
url = {https://www.sciopen.com/article/10.26599/JAC.2026.9221338},
doi = {10.26599/JAC.2026.9221338},
abstract = {Si3N4 fiber-reinforced ceramic composites are promising candidates for high-temperature wave-transparent applications, yet the relationships among composition, interface characteristics, and mechanical performance remain inadequately understood. This study designs three kinds of composites: Si3N4f/BN, Si3N4f/SiO2, and Si3N4f/SiO2-BN and systematically investigates their performances. Results reveal that reaction between BN precursors and silanol groups in the SiO2 matrix during the fabrication of Si3N4f/SiO2-BN enhance the chemical compatibility between fiber and matrix, promoting elemental interdiffusion and forming a thicker interfacial diffusion region. Consequently, the interfacial shear strength of Si3N4f/SiO2-BN is 1.86 and 3.73 times that of Si3N4f/BN and Si3N4f/SiO2, respectively. The stronger fiber-matrix bonding in Si3N4f/SiO2-BN suppresses fiber pull-out, whereas the weaker bonding in the other two composites permits it. Si3N4f/BN primarily exhibits fiber bundle pull-out, whereas Si3N4f/SiO2 shows long single-fiber pull-out, indicating improved damage tolerance. In contrast, Si3N4f/SiO2-BN displays a typical brittle fracture behavior with minimal fiber pull-out and degraded mechanical properties. The excessive interfacial bonding, together with the thermal residual stress arising from the thermal expansion mismatch between the Si3N4 fiber and the matrix, degrades the flexural and compressive strengths. Moreover, this excessive bonding restricts interfacial debonding and fiber pull-out, leading to a brittle fracture mode. Despite differences in interfacial microstructure, all three composites exhibit good dielectric properties. The use of SiO2 and BN matrices effectively reduces both the dielectric constant and dielectric loss tangent of Si3N4 fiber-reinforced ceramic composites. These findings provide valuable insights into the design of high-temperature wave-transparent composites operated in extreme environments.}
}