Achieving Dislocation Strengthening in Hafnium Carbide through High Pressure and High Temperature

Abstract: Dislocations profoundly impact the mechanical behavior of materials. High dislocation density induced strengthening is easily achieved in metallic materials, but it is a challenge in ceramics. Here, we highlight the dislocation engineering of an ultrahigh-temperature ceramic, hafnium carbide (HfC), by high-pressure and high-temperature (HPHT) consolidation. The microstructure and temperature-dependent high-pressure consolidation behaviors were systematically investigated by X-ray diffraction, scanning electron… Show more

“…10 Nevertheless, inspired by the fact that dislocations could enhance the strength of alloys, 11,12 the prefabrication of dislocations to enhance the hardness of ceramics has attracted much attention. For example, dislocations were generated in HfC ceramics by retaining residual stress during cooling of the sintering process, and then hardness was enhanced 13 ; high density of dislocations was developed in ZrN ceramics irradiated by Au 2+ , 14 leading to irradiation hardening.…”

High hardness (TiZr)C ceramic with dislocation networks

“…10 Nevertheless, inspired by the fact that dislocations could enhance the strength of alloys, 11,12 the prefabrication of dislocations to enhance the hardness of ceramics has attracted much attention. For example, dislocations were generated in HfC ceramics by retaining residual stress during cooling of the sintering process, and then hardness was enhanced 13 ; high density of dislocations was developed in ZrN ceramics irradiated by Au 2+ , 14 leading to irradiation hardening.…”

High hardness (TiZr)C ceramic with dislocation networks

Investigating the elastic, mechanical, and thermal properties of polycrystalline Mo2C under high pressure and high temperature

Mechanisms and mechanical properties of high-temperature high-pressure sintered vanadium carbide ceramics