Harnessing elastic anisotropy to achieve low-modulus refractory high-entropy alloys for biomedical applications

Stephan Schönecker, Xiaojie Li, Daixiu Wei, Shogo Nozaki, Hidemi Kato, Levente Vitos, Xiaoqing Li

研究成果: ジャーナルへの寄稿学術論文査読

15 被引用数 (Scopus)

抄録

A high-priority target in the design of new metallic materials for load-bearing implant applications is the reduction of Young's modulus approximating that of cortical bone in the predominant loading direction. Here, we explore how directionally preferential bulk elastic properties of implant materials are achieved by harnessing elastic anisotropy. Specifically focusing on recently proposed biocompatible refractory high-entropy alloys (RHEAs) in the body-centered cubic structure, we conduct systematic density-functional theory calculations to investigate the single-crystal elastic properties of 21 Ti-containing RHEAs. Our results provide evidence that the valence electron count has a dominant influence on elastic anisotropy and crystal directions of low Young's modulus and high torsion modulus in the RHEAs. By means of modeling the orientation distribution function for crystallographic texture, we examine the effect of non-random texture on the anisotropic poly-crystalline Young's modulus and torsion modulus with varying texture sharpness. We adopt fiber textures that can result from rolling and distinct texture orientations that can form during rapid directional solidification. We discuss the potential for lowering Young's modulus in the RHEAs by using single crystals or textured aggregates. Furthermore, we prepare four of the theoretically considered alloys by arc-melting and report their lattice parameters, quasi-isotropic Young's moduli, and Wickers hardnesses.

本文言語英語
論文番号110430
ジャーナルMaterials and Design
215
DOI
出版ステータス出版済み - 2022 3月

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