Litcius/Paper detail

Twinning deformation and toughening effect of Laves phase intermetallics

Xiaobo Wang, Yanru Wu, Jianyu Liu, Xudong Cheng, Kewei Li

2025Journal of Materials Research and Technology5 citationsDOIOpen Access PDF

Abstract

The Laves phases, with a topologically close-packed structure, exhibit superior high-temperature strength, slow self-diffusion rates, and excellent oxidation resistance, making them promising candidates for advanced high-temperature structural materials. However, the industrial application of this material is constrained by its pronounced room-temperature brittleness, which arises from the topologically closed structure. To enhance the room-temperature deformation capability of V 2 Hf Laves phases, this study investigates the effects of Nb alloying and the incorporation of a ductile secondary phase on V 2 Hf. This approach effectively regulates the stacking fault energy and refines the microstructure, thereby promoting twinning and enhancing ductility. The results indicate that the room-temperature fracture toughness of the as-cast Laves phase-based Hf 14 V 64 Nb 22 alloy achieves 8.87 MPa m 1/2 , which corresponds to a 640 % enhancement compared to the as-cast single-phase Laves phases with a toughness of 1.2 MPa m 1/2 . Additionally, the compressive elongation reaches an impressive 26.2 %. The presence of a ductile V(Nb) solid solution promotes twinning in V 2 Hf grains by facilitating crystal orientation adjustment. TEM analysis shows that twinning in the C15 V 2 Hf Laves phase occurs on the (111) plane with a [11-2] direction. The mechanism involves synchronous slip of the αcβ stacking sequence on (111), where atoms in the α layer remain fixed while β layer atoms displace by 1/6[11-2] into c layer positions. Simultaneously, the c layer shifts by 1/6[-211], causing a relative displacement of 1/6[-12-1] between the upper and lower crystals on the (111) plane, forming a Shockley partial dislocation.

Topics & Concepts

Materials scienceLaves phaseCrystal twinningIntermetallicTougheningDeformation (meteorology)MetallurgyPhase (matter)Composite materialMicrostructureToughnessAlloyChemistryOrganic chemistryIntermetallics and Advanced Alloy PropertiesMaterial Properties and ApplicationsAdvancements in Materials Engineering
Twinning deformation and toughening effect of Laves phase intermetallics | Litcius