Establishing microstructure-mechanical property correlation in ZrB2-based ultra-high temperature ceramic composites

Abstract

Abstract The current work focuses on enhancing the flexural strength and fracture toughness of zirconium diboride (ZrB 2 ) reinforced with silicon carbide (SiC) and carbon nanotubes (CNT). The flexural strength has shown to increase by ~ 1.2 times from 322.8 MPa (for ZrB 2 ) to 390.7 MPa and fracture toughness up to 3 times from 3.2 MPam 0.5 (for ZrB 2 ) to 9.5 MPam 0.5 with the synergistic addition of both SiC and CNT in ZrB 2 matrix through energy dissipating mechanisms such as deflection, branching and strong interfacial bonding evidenced from the transmission electron microscopy (TEM). A modified fractal model is used to evaluate the fracture toughness and delineate the contribution of residual stresses, and reinforcements (SiC and CNT) in enhancing the fracture toughness. Interfacial bonding, in terms of a debonding factor, was also evaluated by theoretically predicting the elastic modulus and then correlated with the microstructure along with other mechanical properties of ZrB 2 -SiC-CNT composites.