Exceptional combinations of tensile properties and corrosion resistance in a single-phase Ti1.6ZrNbMo0.35 refractory high-entropy alloy

In this study, we introduce a novel single-phase Ti1·6ZrNbMo0.35 refractory high-entropy alloy (RHEA), synthesized through vacuum arc-melting. The as-cast RHEA demonstrates excellent mechanical properties with a high yield strength of ∼930 MPa and a large tensile strain of ∼15.4 %, achieved through...

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Published inIntermetallics Vol. 171; p. 108349
Main Authors Wang, Hao, Chen, Weiping, Liu, Shiyu, Chu, Chenliang, Huang, Liran, Duan, Jiaqi, Tian, Zhao, Fu, Zhiqiang
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.08.2024
Subjects
Corrosion resistance
Mechanical properties
Refractory high-entropy alloy
Solid solution strengthening
Corrosion resistance
Mechanical properties
Solid solution strengthening
Refractory high-entropy alloy
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Abstract In this study, we introduce a novel single-phase Ti1·6ZrNbMo0.35 refractory high-entropy alloy (RHEA), synthesized through vacuum arc-melting. The as-cast RHEA demonstrates excellent mechanical properties with a high yield strength of ∼930 MPa and a large tensile strain of ∼15.4 %, achieved through severe lattice distortion. Moreover, our investigation reveals the superior corrosion resistance of the RHEA in 3.5 wt% NaCl solution. The remarkable anti-corrosion properties are attributed to the single-phase structure, the increase of Mo6+ oxides in the passive film and continuous passive oxidation of the elements. This work provides a new and significant approach to designing novel RHEAs with excellent combinations of strength-ductility synergy and superior corrosion resistance. [Display omitted] •Ti1·6ZrNbMo0.35 RHEA with a single-phase BCC structure was successfully developed and fabricated.•The as-cast RHEA shows a high tensile yield strength of ∼930 MPa and a large fracture strain of ∼15.4 %.•The as-cast RHEA shows excellent corrosion resistance in 3.5 wt% NaCl solution.•Excellent combinations of mechanical properties and corrosion resistance in RHEA was achieved.
AbstractList In this study, we introduce a novel single-phase Ti1·6ZrNbMo0.35 refractory high-entropy alloy (RHEA), synthesized through vacuum arc-melting. The as-cast RHEA demonstrates excellent mechanical properties with a high yield strength of ∼930 MPa and a large tensile strain of ∼15.4 %, achieved through severe lattice distortion. Moreover, our investigation reveals the superior corrosion resistance of the RHEA in 3.5 wt% NaCl solution. The remarkable anti-corrosion properties are attributed to the single-phase structure, the increase of Mo6+ oxides in the passive film and continuous passive oxidation of the elements. This work provides a new and significant approach to designing novel RHEAs with excellent combinations of strength-ductility synergy and superior corrosion resistance. [Display omitted] •Ti1·6ZrNbMo0.35 RHEA with a single-phase BCC structure was successfully developed and fabricated.•The as-cast RHEA shows a high tensile yield strength of ∼930 MPa and a large fracture strain of ∼15.4 %.•The as-cast RHEA shows excellent corrosion resistance in 3.5 wt% NaCl solution.•Excellent combinations of mechanical properties and corrosion resistance in RHEA was achieved.
ArticleNumber 108349
Author Chen, Weiping
Fu, Zhiqiang
Duan, Jiaqi
Liu, Shiyu
Tian, Zhao
Wang, Hao
Chu, Chenliang
Huang, Liran
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  email: zhiqiangfu2019@scut.edu.cn
  organization: Guangdong Key Laboratory for Advanced Metallic Materials Processing, South China University of Technology, Guangzhou, Guangdong, 510641, China
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Snippet In this study, we introduce a novel single-phase Ti1·6ZrNbMo0.35 refractory high-entropy alloy (RHEA), synthesized through vacuum arc-melting. The as-cast RHEA...
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elsevier
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StartPage 108349
SubjectTerms Corrosion resistance
Mechanical properties
Refractory high-entropy alloy
Solid solution strengthening
Title Exceptional combinations of tensile properties and corrosion resistance in a single-phase Ti1.6ZrNbMo0.35 refractory high-entropy alloy
URI https://dx.doi.org/10.1016/j.intermet.2024.108349
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