TWIP-assisted Zr alloys for medical applications: Design strategy, mechanical properties and first biocompatibility assessment

Tang，Junhui1; Yang，Hongtao2,3; Qian，Bingnan4; Zheng，Yufeng2; Vermaut，Philippe1,5; Prima，Frédéric1; Sun，Fan1

2024-06-10

10.1016/j.jmst.2023.09.051

Journal of Materials Science and Technology   影响因子和分区

1005-0302

This study proposes a novel strategy for the design of a new family of metastable Zr alloys. These alloys offer improved mechanical properties for implants, particularly in applications where conventional stainless steels and Co-Cr alloys are currently used but lack suitability. The design approach is based on the controlled twinning-induced plasticity (TWIP) effect, significantly enhancing the ductility and strain-hardenability of the Zr alloys. In order to draw a “blueprint” for the compositional design of biomedical TWIP (Bio-TWIP) Zr alloys—using only non-toxic elements, the study combines D-electron phase stability calculations (specifically bond order (B) and mean d-orbital energy (M)) with a systematic experimental screening of active deformation mechanisms within the Zr-Nb-Sn alloy system. This research aids in accurately identifying the TWIP line, which signifies the mechanism shift between TWIP and classic slip as the primary deformation mechanism. To demonstrate the efficacy of the TWIP mechanism in enhancing mechanical properties, Zr-12Nb-2Sn, Zr-13Nb-1Sn, and Zr-14Nb-3Sn alloys are selected. Results indicate that the TWIP mechanism leads to a significant improvement of strain-hardening rate and a uniform elongation of ∼20% in Zr-12Nb-2Sn, which displays both {332}<113> mechanical twinning and dislocation slip as the primary deformation mechanisms. Conversely, Zr-14Nb-3Sn exhibits the typical mechanical properties found in stable body-centered cubic (BCC) alloys, characterized by the sole occurrence of dislocation slip. Cell viability tests confirm the superior biocompatibility of Zr-Nb-based alloys with deformation twins on the surface, in line with existing literature. Based on the whole set of results, a comprehensive design diagram is proposed.

Biocompatibility Biomedical materials Bo‾ -Md‾ diagram Strain-hardening Twinning-induced plasticity (TWIP) Zr alloys

SCI ; EI

英语

其他

MATERIALS SCIENCE

2-s2.0-85179013703

Scopus

1.Chimie ParisTech,CNRS-UMR8247,Institut de Recherche de Chimie Paris,PSL Research University,Paris,75005,France
2.School of Materials Science and Engineering,Peking University,Beijing,100871,China
3.School of Engineering Medicine,Beihang University,Beijing,100191,China
4.Department of Mechanical and Energy Engineering,Southern University of Science and Technology,Shenzhen,518055,China
5.Sorbonne University,UPMC University Paris,Paris,UFR926,75005,France

Tang，Junhui,Yang，Hongtao,Qian，Bingnan,et al. TWIP-assisted Zr alloys for medical applications: Design strategy, mechanical properties and first biocompatibility assessment[J]. Journal of Materials Science and Technology,2024,184:32-42.

Tang，Junhui.,Yang，Hongtao.,Qian，Bingnan.,Zheng，Yufeng.,Vermaut，Philippe.,...&Sun，Fan.(2024).TWIP-assisted Zr alloys for medical applications: Design strategy, mechanical properties and first biocompatibility assessment.Journal of Materials Science and Technology,184,32-42.

Tang，Junhui,et al."TWIP-assisted Zr alloys for medical applications: Design strategy, mechanical properties and first biocompatibility assessment".Journal of Materials Science and Technology 184(2024):32-42.