Doping B or C to improve the wear resistance of (Ti42.5Zr42.5Nb10Ta5)93Mo7 refractory high-entropy alloy via grain boundary plasticization

IF 6.1 1区工程技术 Q1 ENGINEERING, MECHANICAL

Wear Pub Date : 2025-10-11 DOI:10.1016/j.wear.2025.206385

Juan Han , Naiyi Lei , Dakui Zhou , Shaolei Long , Zhentao Yu , Yanliang Yi

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引用次数: 0

Abstract

RHEAs exhibit low room-temperature ductility, which severely restricts their processing and industrial applications. In this work, the high strength (Ti_42.5Zr_42.5Nb₁₀Ta₅)₉₃Mo₇ was selected as the base alloy and grain boundary engineering through doping B and C was utilized to achieve an optimal balance between mechanical properties and wear resistance. The tensile strength and plasticity of the (Ti_42.5Zr_42.5Nb₁₀Ta₅)₉₃Mo₇ refractory high-entropy alloys (RHEAs) are simultaneously enhanced with the addition of 0.05 at.% B or 0.05 at.% C. The effects of doping B or C on tribological properties of the (Ti_42.5Zr_42.5Nb₁₀Ta₅)₉₃Mo₇ RHEAs sliding against Si₃N₄ balls under different sliding distance were systematically investigated. The results show that B or C segregates at grain boundaries (GBs) and enhance the GB cohesion, thus significantly improving the strength and plasticity of RHEAs. After doping 0.05 at.% B, the yield strength increases from 956 MPa to 983 MPa and the elongation increases from 1.81 % to 4.97 %. Specifically, the yield strength is 1047 MPa for the alloy doped with 0.05 at.% C, and the elongation skyrockets to 26.51 %. The RHEA-C alloy exhibits the lowest wear rate under different sliding distance due to its highest strength and optimal plasticity. Additionally, the wear rates of the three RHEAs decrease firstly and then increase with increasing sliding distance from 18 m to 144 m. After 18 m sliding, the wear mechanism is severe abrasive wear, adhesive wear and slight oxidation wear. As the sliding distance increased to 108 m, the wear mechanism of the alloy is mainly dominated by oxidative wear, resulting in the best wear resistance, but the cracks and spalling pits occur in the oxide layer as the sliding distance further increased. The RHEAs designed in this work are applicable to numerous industries, including defense, transportation, and aerospace due to its good mechanical properties and wear resistance.

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掺杂B或C通过晶界塑化提高（Ti42.5Zr42.5Nb10Ta5）93Mo7耐火高熵合金的耐磨性

RHEAs具有较低的室温延展性，这严重限制了其加工和工业应用。本研究选择高强度（Ti42.5Zr42.5Nb10Ta5）93Mo7作为基体合金，通过掺杂B和C进行晶界工程，达到力学性能和耐磨性的最佳平衡。添加0.05 at时，（Ti42.5Zr42.5Nb10Ta5）93Mo7耐火高熵合金（RHEAs）的抗拉强度和塑性同时增强。% B或0.05 at。系统研究了B和C对（Ti42.5Zr42.5Nb10Ta5）93Mo7 RHEAs在不同滑动距离下与Si3N4球摩擦性能的影响。结果表明：B或C在晶界处偏析，增强了晶界内聚，显著提高了合金的强度和塑性；在掺杂0.05 at后。% B时，屈服强度由956 MPa提高到983 MPa，伸长率由1.81%提高到4.97%。其中，掺0.05 at的合金屈服强度为1047 MPa。% C，伸长率达到26.51%。RHEA-C合金具有最高的强度和最佳的塑性，在不同滑动距离下的磨损率最低。从18 m到144 m，随着滑动距离的增加，3种合金的磨损率先减小后增大。滑动18m后，磨损机理为严重的磨粒磨损、黏着磨损和轻微的氧化磨损。当滑动距离增加到108 m时，合金的磨损机制以氧化磨损为主，耐磨性最佳，但随着滑动距离的进一步增加，氧化层出现裂纹和剥落坑。由于其良好的机械性能和耐磨性，本工作中设计的rhea适用于许多行业，包括国防，运输和航空航天。

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来源期刊

Wear 工程技术-材料科学：综合

CiteScore

8.80

自引率

8.00%

发文量

280

审稿时长

47 days

期刊介绍： Wear journal is dedicated to the advancement of basic and applied knowledge concerning the nature of wear of materials. Broadly, topics of interest range from development of fundamental understanding of the mechanisms of wear to innovative solutions to practical engineering problems. Authors of experimental studies are expected to comment on the repeatability of the data, and whenever possible, conduct multiple measurements under similar testing conditions. Further, Wear embraces the highest standards of professional ethics, and the detection of matching content, either in written or graphical form, from other publications by the current authors or by others, may result in rejection.