High-temperature stable refractory high-entropy nanoalloys with enhanced sinterability

TL;DR

This study develops refractory high-entropy nanoalloys with high sinterability and exceptional stability at 1300°C, combining innovative fabrication and alloying strategies to prevent grain growth.

Contribution

It introduces a method to produce high-temperature stable nanoalloys with enhanced sinterability using planetary ball milling and spark plasma sintering, incorporating Ni to improve densification.

Findings

Achieved 93-96% density with 50-100 nm grains at 1300°C

Maintained <150 nm grains after 5 hours at 1300°C

Ni addition promotes sintering while ensuring high-temperature stability

Abstract

Nanocrystalline alloys (nanoalloys) are prone to grain growth. It is known that grain boundary segregation and precipitation can stabilize nanoalloys, but the stabilization becomes less effective at high temperatures and adding grain growth inhibitors often reduces sinterability. Herein, we have simultaneously achieved improved sinterability and exceptional high-temperature stability for a class of MoNbTaTiW-based refractory high-entropy nanoalloys (RHENs). Bulk pellets of RHENs were fabricated through planetary ball milling and spark plasma sintering, achieving 93-96% relative densities with 50-100 nm grain sizes for three compositions. For example, Mo17.8Nb17.8Ta17.8Ti17.8W17.8Ni6Zr5 sintered at 1300 {\deg}C attained ~96% relative density with ~55 nm mean grain size. Moreover, these RHENs exhibited exceptional stability at 1300 {\deg}C. Both Ti17.8Nb17.8Mo17.8Ta17.8W17.8Ni6Zr5 and Mo18.8Nb18.8Ta18.8Ti18.8W18.8Ni6 retained <150 nm grain sizes with >96% of the theoretical densities after five hours annealing at 1300 {\deg}C. Notably, the addition of Ni, a well-known sintering aid for activated sintering of refractory metals such as W and Mo, in high-entropy MoNbTaTiW can promote sintering while maintaining high-temperature stability against rapid grain growth, which can be explained by hypothesized effects of high-entropy grain boundaries. These RHENs possess some of the highest temperature stability achieved for nanoalloys and ultrafine-grained metals.