Litcius/Paper detail

Ultra-incompressible High-Entropy Diborides

Xiaoliang Zhang, Weiwei Li, Hua Tian, Junxiu Liu, Cong Li, Hongliang Dong, Jian Chen, Meng Song, Bin Chen, H. W. Sheng, Shanmin Wang, Dongzhou Zhang, Hengzhong Zhang

2021The Journal of Physical Chemistry Letters33 citationsDOI

Abstract

Transition metal borides are commonly hard and incompressible, offering great opportunities for advanced applications under extreme conditions. Recent studies show that the hardness of high-entropy borides may exceed that of their constituent simple borides due to the "cocktail effect". However, how high-entropy borides deform elastically remains largely unknown. Here, we show that two newly synthesized high-entropy diborides are ultra-incompressible, attaining ∼90% of the incompressibility of single-crystalline diamond and exhibiting a 50-60% enhancement over the density functional theory predictions. This unusual behavior is attributed to a Hall-Petch-like effect resulting from nanosizing under high pressure, which increases the bulk moduli through dynamic dislocation interactions and creation of stacking faults. The exceptionally low compressibility, together with their high phase stabilities, high hardness, and high electric conductance, renders them promising candidates for electromechanics and microelectronic devices that demand strong resistance to environmental impacts, in addition to traditional grinding and abrading.

Topics & Concepts

Materials scienceCompressibilityDiamondCondensed matter physicsEntropy (arrow of time)GrindingHigh entropy alloysThermodynamicsMetallurgyMicrostructurePhysicsDiamond and Carbon-based Materials ResearchAdvanced materials and compositesMetal and Thin Film Mechanics