Litcius/Paper detail

Mechanical properties of borothermally synthesized zirconium diboride at elevated temperatures

Alec C. Murchie, Jeremy Watts, William G. Fahrenholtz, Gregory E. Hilmas

2021International Journal of Applied Ceramic Technology13 citationsDOI

Abstract

Abstract The mechanical properties of a nominally phase pure ZrB 2 ceramic were measured up to 2300°C in an argon atmosphere. ZrB 2 was hot pressed at 2000°C utilizing borothermally synthesized powder from high purity ZrO 2 and B raw materials. The relative density of the ceramics was about 95% with an average ZrB 2 grain size of 8.8 µm. The room temperature flexural strength was 447 MPa, with strength decreasing to 196 MPa at 1800°C, and then increasing to 360 MPa at 2300°C. The strength up to 1800°C was likely controlled by a combination of effects: surface damage from oxidation of the specimens, stress relaxation, and decreases in the elastic modulus. The strength above 1800°C was controlled by flaws in the range consistent with sizes of the maximum ZrB 2 grain size and the largest pores. Fracture toughness was 2.3 MPa·m 1/2 at room temperature, increasing to 3.1 MPa·m 1/2 at 2200°C. The use of higher purity starting materials improved the mechanical behavior in the ultra‐high temperature regime compared to previous studies.

Topics & Concepts

Materials scienceFlexural strengthComposite materialCeramicFracture toughnessZirconium diborideGrain sizeAtmospheric temperature rangeRelative densityZirconiumMicrostructureMetallurgyPhysicsMeteorologyAdvanced ceramic materials synthesisAdvanced materials and compositesMXene and MAX Phase Materials