Litcius/Paper detail

Liquid metal assistant self-propagating high-temperature synthesis of S-containing high-entropy MAX-phase materials

Donglong Bai, Qiang Wang, Bin Deng, Yang Li, Ao Huang, Zitong Cheng, Zhao Yun, Jing Li, Yang Li, Wei Yao, Jianguang Xu

2024Journal of Material Science and Technology19 citationsDOIOpen Access PDF

Abstract

Due to their high-entropy effects, the high-entropy (HE) MAX-phase materials improve the comprehensive performance of MAX phases, opening up more possibilities for practical engineering applications. However, it is still challenging to obtain S-containing high-entropy MAX phases because of the high volatilization behavior of sulfur, suffering from issues such as high reaction temperature and long reaction time of traditional synthesis methods. This paper proposes a novel process named as liquid metal assistant self-propagating high-temperature synthesis (LMA-SHS) for efficient synthesis of high-purity S-containing high-entropy MAX-phase materials. Low-melting-point metal (Sn or In) has been introduced into the raw mixture and melted into a liquid phase during the early stage of the SHS reaction. By serving as a “binder” between transition metal atoms of the M-site due to the negative mixing enthalpy, this liquid phase can accelerate mass and heat transfer during the SHS process, ensuring a uniform solid solution of each element and realizing the synthesis of high-purity (TiNbVZr) 2 SC in an extremely short time. The synthesis method for high-entropy MAX-phase materials developed in this study, i.e., LMA-SHS, showing very short reaction time, low energy consumption, high yield, and low cost, has the promise to be a general energy- and resource-efficient route towards high-purity HE materials.

Topics & Concepts

MetalMaterials scienceThermodynamicsPhase (matter)ChemistryPhysicsMetallurgyOrganic chemistryMXene and MAX Phase Materials2D Materials and ApplicationsIntermetallics and Advanced Alloy Properties