Understanding the mechanical properties of two-phase nanocrystalline AlCrFeMoNbNi high-entropy alloy evaluated by nanoindentation

IF 2.7 4区材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY Journal of Materials Research Pub Date : 2024-07-02 DOI:10.1557/s43578-024-01382-w

V. Madhu Babu, Deekshith G. Kalali, Harita Seekala, P. Sudharshan Phani, K. Bhanu Sankara Rao, Koteswararao V. Rajulapati

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Abstract

Nanocrystalline two-phase AlCrFeMoNbNi high-entropy alloy (HEA) was produced using mechanical alloying (MA) and high-pressure torsion (HPT), with an average grain size of 10 ± 2 nm. Nanoindentation testing was performed to measure the hardness from which the strengthening contributions via various mechanisms such as strain hardening, solid solution strengthening, frictional stress and grain boundary strengthening are assessed. A Hall–Petch coefficient of 0.135 MPa \(\sqrt{\text{m}}\) is estimated from this analysis, which is much lower than that for comparable alloys. A very low activation volume, for plastic deformation, of 3.4 b³ was measured from strain rate dependent nanoindentation testing, which is indicative of grain boundary mediated plastic deformation. Furthermore, the estimated activation energy of 171 kJ/mol measured from nanoindentation testing, is comparable to that for grain boundary diffusion in Cantor alloy. These experimental results provide insights on the deformation response of nanocrystalline two-phase AlCrFeMoNbNi HEA at an extremely fine grain size of around 10 nm.

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通过纳米压痕评估了解两相纳米晶铝铬铁钼铌镍高熵合金的力学性能

利用机械合金化（MA）和高压扭转（HPT）技术生产了纳米晶两相铝铬铁钼铌镍高熵合金（HEA），其平均晶粒尺寸为 10 ± 2 nm。通过纳米压痕测试测量了硬度，并由此评估了应变硬化、固溶强化、摩擦应力和晶界强化等各种机制对强化的贡献。根据该分析估计，霍尔-佩奇系数为 0.135 MPa （\sqrt\text{m}}\），远低于同类合金的霍尔-佩奇系数。应变速率依赖性纳米压痕测试测得的塑性变形活化体积非常低，为 3.4 b3，这表明了晶界介导的塑性变形。此外，纳米压痕测试测得的活化能为 171 kJ/mol，与康托合金中晶界扩散的活化能相当。这些实验结果为纳米晶两相 AlCrFeMoNbNi HEA 在约 10 纳米的极细晶粒尺寸下的变形响应提供了见解。

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来源期刊

Journal of Materials Research 工程技术-材料科学：综合

CiteScore

4.50

自引率

3.70%

发文量

362

审稿时长

2.8 months

期刊介绍： Journal of Materials Research (JMR) publishes the latest advances about the creation of new materials and materials with novel functionalities, fundamental understanding of processes that control the response of materials, and development of materials with significant performance improvements relative to state of the art materials. JMR welcomes papers that highlight novel processing techniques, the application and development of new analytical tools, and interpretation of fundamental materials science to achieve enhanced materials properties and uses. Materials research papers in the following topical areas are welcome. • Novel materials discovery • Electronic, photonic and magnetic materials • Energy Conversion and storage materials • New thermal and structural materials • Soft materials • Biomaterials and related topics • Nanoscale science and technology • Advances in materials characterization methods and techniques • Computational materials science, modeling and theory