Synergetic roles of ZrC and SiC in ternary ZrB2–SiC–ZrC ceramics

Abstract SiC and ZrC were used to tailor microstructures and improve properties of hot-pressed ZrB 2 -based ceramics. Grain growth kinetics and microstructural stability during annealing were studied. Compared with ZrC, SiC grains grew slower and were more effective to inhibit ZrB 2 grain growth. ZrB 2 –20SiC–20ZrC (number in vol%) had the finest and the most stable microstructure, indicating synergistic effects of SiC and ZrC on grain growth. Also, ZrC and SiC played different roles on mechanical properties. Thermal residual stresses on SiC particles decreased from ∼800 MPa in ZrB 2 –SiC to ∼400 MPa in ZrB 2 –SiC–ZrC, due to the plastic deformation of ZrC. Crack deflection around ZrC grains was the major toughening mechanism (∼1 MPa m 1/2 ) in ZrB 2 –ZrC-based ceramics. The flexural strengths of ZrB 2 –SiC–ZrC were improved to 800 MPa, due to smaller SiC cluster sizes and lower residual stresses. ZrB 2 –20ZrC had the largest Weibull modulus of 14.1, and the modulus decreased with an increase in SiC content.