E. S. Panina, N. Yu. Yurchenko, A. A. Tozhibaev, M. V. Mishunin, S. V. Zherebtsov, N. D. Stepanov
{"title":"A Study of the Structure and Mechanical Properties of Nb-Mo-Co-X (X = Hf, Zr, Ti) Refractory High-Entropy Alloys","authors":"E. S. Panina, N. Yu. Yurchenko, A. A. Tozhibaev, M. V. Mishunin, S. V. Zherebtsov, N. D. Stepanov","doi":"10.1134/S1029959923060061","DOIUrl":null,"url":null,"abstract":"<p>Refractory high-entropy alloys (HEAs) are a new class of metallic materials based on group 4–6 elements of the periodic table with possible additions of Al, Si, Re, C, or B. Some single-phase refractory HEAs can maintain high strength up to 1600°C, while multiphase compositions have more attractive specific properties at temperatures up to 1200°C. Here we examine the structure and mechanical properties of refractory HEAs Nb<sub>30</sub>Mo<sub>30</sub>Co<sub>20</sub>Hf<sub>20</sub>, Nb<sub>30</sub>Mo<sub>30</sub>Co<sub>20</sub>Zr<sub>20</sub>, and Nb<sub>30</sub>Mo<sub>30</sub>Co<sub>20</sub>Ti<sub>20</sub> (at %). The alloys consisted of an intermetallic B2 matrix and particles of a disordered bcc phase, as well as a minor volume fraction of additional bcc (Nb<sub>30</sub>Mo<sub>30</sub>Co<sub>20</sub>Hf<sub>20</sub> and Nb<sub>30</sub>Mo<sub>30</sub>Co<sub>20</sub>Zr<sub>20</sub>) or fcc (Nb<sub>30</sub>Mo<sub>30</sub>Co<sub>20</sub>Ti<sub>20</sub>) phases. When tested for uniaxial compression, Nb<sub>30</sub>Mo<sub>30</sub>Co<sub>20</sub>Ti<sub>20</sub> alloy showed a higher yield strength in the temperature range of 22–1000°C than Nb<sub>30</sub>Mo<sub>30</sub>Co<sub>20</sub>Hf<sub>20</sub> and Nb<sub>30</sub>Mo<sub>30</sub>Co<sub>20</sub>Zr<sub>20</sub> alloys. Nb<sub>30</sub>Mo<sub>30</sub>Co<sub>20</sub>Zr<sub>20</sub> alloy did not fail at temperatures of 22–800°C to a given 50% strain, while Nb<sub>30</sub>Mo<sub>30</sub>Co<sub>20</sub>Ti<sub>20</sub> alloy turned out to be brittle. All alloys demonstrated high strain hardening in the temperature range of 22–800°C, and they can compete in terms of specific strength with commercial nickel and cobalt superalloys.</p>","PeriodicalId":726,"journal":{"name":"Physical Mesomechanics","volume":"26 6","pages":"666 - 677"},"PeriodicalIF":1.8000,"publicationDate":"2023-12-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Physical Mesomechanics","FirstCategoryId":"88","ListUrlMain":"https://link.springer.com/article/10.1134/S1029959923060061","RegionNum":4,"RegionCategory":"材料科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"MATERIALS SCIENCE, CHARACTERIZATION & TESTING","Score":null,"Total":0}
引用次数: 0
Abstract
Refractory high-entropy alloys (HEAs) are a new class of metallic materials based on group 4–6 elements of the periodic table with possible additions of Al, Si, Re, C, or B. Some single-phase refractory HEAs can maintain high strength up to 1600°C, while multiphase compositions have more attractive specific properties at temperatures up to 1200°C. Here we examine the structure and mechanical properties of refractory HEAs Nb30Mo30Co20Hf20, Nb30Mo30Co20Zr20, and Nb30Mo30Co20Ti20 (at %). The alloys consisted of an intermetallic B2 matrix and particles of a disordered bcc phase, as well as a minor volume fraction of additional bcc (Nb30Mo30Co20Hf20 and Nb30Mo30Co20Zr20) or fcc (Nb30Mo30Co20Ti20) phases. When tested for uniaxial compression, Nb30Mo30Co20Ti20 alloy showed a higher yield strength in the temperature range of 22–1000°C than Nb30Mo30Co20Hf20 and Nb30Mo30Co20Zr20 alloys. Nb30Mo30Co20Zr20 alloy did not fail at temperatures of 22–800°C to a given 50% strain, while Nb30Mo30Co20Ti20 alloy turned out to be brittle. All alloys demonstrated high strain hardening in the temperature range of 22–800°C, and they can compete in terms of specific strength with commercial nickel and cobalt superalloys.
期刊介绍:
The journal provides an international medium for the publication of theoretical and experimental studies and reviews related in the physical mesomechanics and also solid-state physics, mechanics, materials science, geodynamics, non-destructive testing and in a large number of other fields where the physical mesomechanics may be used extensively. Papers dealing with the processing, characterization, structure and physical properties and computational aspects of the mesomechanics of heterogeneous media, fracture mesomechanics, physical mesomechanics of materials, mesomechanics applications for geodynamics and tectonics, mesomechanics of smart materials and materials for electronics, non-destructive testing are viewed as suitable for publication.