Ultra-high temperature ceramics (UHTCs) are candidate materials for use in extreme environments owing to their melting point exceeding 3000°C and excellent ablation resistance. Despite the interesting combination of thermo-mechanical properties, they remain susceptible to brittle failure. One route to mitigate the strength-ductility paradox is the formation of hierarchical structures, where several mechanisms can act synergystically on different length scales. Here we explore how to promote and tailor a multi-scale microstructure arrangement in ZrB2 materials sintered in the presence of transition metals (TM), leading to particular morphology of the grains, known as core-shell microstructures. These materials are composed of a (Zr,TM)B2 solid solution shell around a nominally pure boride grain core. Super-saturated solid solutions lead to the precipitation of nano-inclusions within a micron-sized boride grain matrix. Phase stability diagrams enabled identification of the conditions of oxygen activity that drive precipitation of either metallic or carbide nano-inclusions, Figure 1. The strength behavior of these core-shelled ceramics at temperatures up to 2100°C will be presented and related to the microstructural features. Strengths over 1 GPa 1800°C were measured. Fracture analysis and transmission electron microscopy proved this behavior was due to the hierarchical hybrid structure with nanoparticles homogeneously dispersed in micrometric ceramic grains.
Ultra-high temperature ceramics with exceptional strength at elevated temperature
Laura Silvestroni;Nicola Gilli;Diletta Sciti;
2022
Abstract
Ultra-high temperature ceramics (UHTCs) are candidate materials for use in extreme environments owing to their melting point exceeding 3000°C and excellent ablation resistance. Despite the interesting combination of thermo-mechanical properties, they remain susceptible to brittle failure. One route to mitigate the strength-ductility paradox is the formation of hierarchical structures, where several mechanisms can act synergystically on different length scales. Here we explore how to promote and tailor a multi-scale microstructure arrangement in ZrB2 materials sintered in the presence of transition metals (TM), leading to particular morphology of the grains, known as core-shell microstructures. These materials are composed of a (Zr,TM)B2 solid solution shell around a nominally pure boride grain core. Super-saturated solid solutions lead to the precipitation of nano-inclusions within a micron-sized boride grain matrix. Phase stability diagrams enabled identification of the conditions of oxygen activity that drive precipitation of either metallic or carbide nano-inclusions, Figure 1. The strength behavior of these core-shelled ceramics at temperatures up to 2100°C will be presented and related to the microstructural features. Strengths over 1 GPa 1800°C were measured. Fracture analysis and transmission electron microscopy proved this behavior was due to the hierarchical hybrid structure with nanoparticles homogeneously dispersed in micrometric ceramic grains.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.