Development of an equiatomic octonary TiNbTaZrMoHfWCr super-high-entropy alloy for biomedical applications

Tadaaki Matsuzaka; Akira Hyakubu; Yong Seong Kim; Aira Matsugaki; Takeshi Nagase; Takuya Ishimoto; Ryosuke Ozasa; Hyoung Seop Kim; Tomoji Mizuguchi; Ozkan Gokcekaya; Takayoshi Nakano

doi:10.1016/j.matchemphys.2024.129120

Development of an equiatomic octonary TiNbTaZrMoHfWCr super-high-entropy alloy for biomedical applications

Tadaaki Matsuzaka, Akira Hyakubu, Yong Seong Kim, Aira Matsugaki, Takeshi Nagase, Takuya Ishimoto, Ryosuke Ozasa, Hyoung Seop Kim, Tomoji Mizuguchi, Ozkan Gokcekaya, Takayoshi Nakano^*

^*Corresponding author for this work

Center for Aluminum and advanced Materials Research and International Collaboration, Institute of Light Metals

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

A super-high-entropy alloy (SHEA) with ΔS_mix ≥ 2.0R (where R is the gas constant) was designed to produce metallic materials with superior mechanical properties to conventional alloys. As an alternative to conventional quinary high-entropy alloys (HEAs), herein, octonary SHEAs for biomedical applications (BioSHEAs) are proposed for the first time, and the TiNbTaZrMoHfWCr BioSHEA was fabricated. Arc-melted BioSHEA exhibited an extremely high yield strength of 1953 ± 84 MPa, which was approximately 550 MPa higher than that of the quinary TiNbTaZrMo BioHEA. This yield strength is considerably higher than that estimated by the rule of mixtures for pure metals, confirming the achievement of significant solid-solution strengthening induced by a supermulticomponent solid solution composed of elements with different atomic radii. Its biocompatibility was comparable to that of pure Ti and the quinary BioHEA, and superior to that of SUS316L. This study demonstrates the validity of a novel entropy-based guideline for increasing the mixing entropy to achieve metallic materials with ultrahigh strength.

Original language	English
Article number	129120
Journal	Materials Chemistry and Physics
Volume	316
DOIs	https://doi.org/10.1016/j.matchemphys.2024.129120
State	Published - 2024/04/01

Keywords

BioSHEAs
Octonary system
Solid-solution strengthening
Super-high-entropy alloys (SHEAs)
Supermulticomponent

ASJC Scopus subject areas

General Materials Science
Condensed Matter Physics

Access to Document

10.1016/j.matchemphys.2024.129120

Cite this

@article{52f4ee5a325041d8a26a55340500861c,

title = "Development of an equiatomic octonary TiNbTaZrMoHfWCr super-high-entropy alloy for biomedical applications",

abstract = "A super-high-entropy alloy (SHEA) with ΔSmix ≥ 2.0R (where R is the gas constant) was designed to produce metallic materials with superior mechanical properties to conventional alloys. As an alternative to conventional quinary high-entropy alloys (HEAs), herein, octonary SHEAs for biomedical applications (BioSHEAs) are proposed for the first time, and the TiNbTaZrMoHfWCr BioSHEA was fabricated. Arc-melted BioSHEA exhibited an extremely high yield strength of 1953 ± 84 MPa, which was approximately 550 MPa higher than that of the quinary TiNbTaZrMo BioHEA. This yield strength is considerably higher than that estimated by the rule of mixtures for pure metals, confirming the achievement of significant solid-solution strengthening induced by a supermulticomponent solid solution composed of elements with different atomic radii. Its biocompatibility was comparable to that of pure Ti and the quinary BioHEA, and superior to that of SUS316L. This study demonstrates the validity of a novel entropy-based guideline for increasing the mixing entropy to achieve metallic materials with ultrahigh strength.",

keywords = "BioSHEAs, Octonary system, Solid-solution strengthening, Super-high-entropy alloys (SHEAs), Supermulticomponent",

author = "Tadaaki Matsuzaka and Akira Hyakubu and Kim, {Yong Seong} and Aira Matsugaki and Takeshi Nagase and Takuya Ishimoto and Ryosuke Ozasa and Kim, {Hyoung Seop} and Tomoji Mizuguchi and Ozkan Gokcekaya and Takayoshi Nakano",

note = "Publisher Copyright: {\textcopyright} 2024 The Authors",

year = "2024",

month = apr,

day = "1",

doi = "10.1016/j.matchemphys.2024.129120",

language = "英語",

volume = "316",

journal = "Materials Chemistry and Physics",

issn = "0254-0584",

publisher = "Elsevier B.V.",

}

TY - JOUR

T1 - Development of an equiatomic octonary TiNbTaZrMoHfWCr super-high-entropy alloy for biomedical applications

AU - Matsuzaka, Tadaaki

AU - Hyakubu, Akira

AU - Kim, Yong Seong

AU - Matsugaki, Aira

AU - Nagase, Takeshi

AU - Ishimoto, Takuya

AU - Ozasa, Ryosuke

AU - Kim, Hyoung Seop

AU - Mizuguchi, Tomoji

AU - Gokcekaya, Ozkan

AU - Nakano, Takayoshi

PY - 2024/4/1

Y1 - 2024/4/1

N2 - A super-high-entropy alloy (SHEA) with ΔSmix ≥ 2.0R (where R is the gas constant) was designed to produce metallic materials with superior mechanical properties to conventional alloys. As an alternative to conventional quinary high-entropy alloys (HEAs), herein, octonary SHEAs for biomedical applications (BioSHEAs) are proposed for the first time, and the TiNbTaZrMoHfWCr BioSHEA was fabricated. Arc-melted BioSHEA exhibited an extremely high yield strength of 1953 ± 84 MPa, which was approximately 550 MPa higher than that of the quinary TiNbTaZrMo BioHEA. This yield strength is considerably higher than that estimated by the rule of mixtures for pure metals, confirming the achievement of significant solid-solution strengthening induced by a supermulticomponent solid solution composed of elements with different atomic radii. Its biocompatibility was comparable to that of pure Ti and the quinary BioHEA, and superior to that of SUS316L. This study demonstrates the validity of a novel entropy-based guideline for increasing the mixing entropy to achieve metallic materials with ultrahigh strength.

AB - A super-high-entropy alloy (SHEA) with ΔSmix ≥ 2.0R (where R is the gas constant) was designed to produce metallic materials with superior mechanical properties to conventional alloys. As an alternative to conventional quinary high-entropy alloys (HEAs), herein, octonary SHEAs for biomedical applications (BioSHEAs) are proposed for the first time, and the TiNbTaZrMoHfWCr BioSHEA was fabricated. Arc-melted BioSHEA exhibited an extremely high yield strength of 1953 ± 84 MPa, which was approximately 550 MPa higher than that of the quinary TiNbTaZrMo BioHEA. This yield strength is considerably higher than that estimated by the rule of mixtures for pure metals, confirming the achievement of significant solid-solution strengthening induced by a supermulticomponent solid solution composed of elements with different atomic radii. Its biocompatibility was comparable to that of pure Ti and the quinary BioHEA, and superior to that of SUS316L. This study demonstrates the validity of a novel entropy-based guideline for increasing the mixing entropy to achieve metallic materials with ultrahigh strength.

KW - BioSHEAs

KW - Octonary system

KW - Solid-solution strengthening

KW - Super-high-entropy alloys (SHEAs)

KW - Supermulticomponent

UR - http://www.scopus.com/inward/record.url?scp=85186472551&partnerID=8YFLogxK

U2 - 10.1016/j.matchemphys.2024.129120

DO - 10.1016/j.matchemphys.2024.129120

M3 - 学術論文

AN - SCOPUS:85186472551

SN - 0254-0584

VL - 316

JO - Materials Chemistry and Physics

JF - Materials Chemistry and Physics

M1 - 129120

ER -

Development of an equiatomic octonary TiNbTaZrMoHfWCr super-high-entropy alloy for biomedical applications

Abstract

Keywords

ASJC Scopus subject areas

Access to Document

Fingerprint

Cite this