Negative Mixing Enthalpy Solid Solutions Deliver High Strength and Ductility

Overview

Journal Nature

Specialty Science

Date 2024 Jan 3

PMID 38172639

Authors

Zibing An

Ang Li

Shengcheng Mao

Tao Yang

Lingyu Zhu

Rui Wang

Zhaoxuan Wu

Bin Zhang

Ruiwen Shao

Cheng Jiang

Boxuan Cao

Caijuan Shi

Yang Ren

Cheng Liu

Haibo Long

Jianfei Zhang

Wei Li

Feng He

Ligang Sun

Junbo Zhao

Luyan Yang

Xiaoyuan Zhou

Xiao Wei

Yunmin Chen

Zhouguang Lu

Fuzeng Ren

Chain-Tsuan Liu

Ze Zhang

Xiaodong Han

Affiliations

Soon will be listed here.

Abstract

Body-centred cubic refractory multi-principal element alloys (MPEAs), with several refractory metal elements as constituents and featuring a yield strength greater than one gigapascal, are promising materials to meet the demands of aggressive structural applications. Their low-to-no tensile ductility at room temperature, however, limits their processability and scaled-up application. Here we present a HfNbTiVAl alloy that shows remarkable tensile ductility (roughly 20%) and ultrahigh yield strength (roughly 1,390 megapascals). Notably, these are among the best synergies compared with other related alloys. Such superb synergies derive from the addition of aluminium to the HfNbTiV alloy, resulting in a negative mixing enthalpy solid solution, which promotes strength and favours the formation of hierarchical chemical fluctuations (HCFs). The HCFs span many length scales, ranging from submicrometre to atomic scale, and create a high density of diffusive boundaries that act as effective barriers for dislocation motion. Consequently, versatile dislocation configurations are sequentially stimulated, enabling the alloy to accommodate plastic deformation while fostering substantial interactions that give rise to two unusual strain-hardening rate upturns. Thus, plastic instability is significantly delayed, which expands the plastic regime as ultralarge tensile ductility. This study provides valuable insights into achieving a synergistic combination of ultrahigh strength and large tensile ductility in MPEAs.

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