通过低温预时效追求超高强度-韧性钴铬镍基中熵合金

IF 11.2 1区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Journal of Materials Science & Technology Pub Date : 2024-10-05 DOI:10.1016/j.jmst.2024.09.025
A.X. Li, K.W. Kang, J.S. Zhang, M.K. Xu, D. Huang, S.K. Liu, Y.T. Jiang, G. Li
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引用次数: 0

摘要

开发具有千兆帕强度和优异延展性的高性能合金对现代工程应用至关重要。多组分高/中熵合金(H/MEAs)的概念为设计此类合金提供了一种创新方法。在这项研究中,我们开发了 Co1.5CrNi1.5Al0.2Ti0.2 MEA,通过低温预时效和退火处理,该合金在室温下表现出卓越的机械性能。拉伸测试表明,MEA 具有 20±±0785 兆帕的超高屈服强度、2365 ±±70 兆帕的极限拉伸强度和 15.8% ±±1.7% 的优异延展性。优异的拉伸性能归功于由超细晶粒(UFG)和细晶粒(FG)区域组成的完全再结晶异质结构(HGS)的形成,以及连贯的纳米级片状 L12 沉淀的不连续析出。在变形过程中,超细晶粒区和细晶粒区之间的机械不相容性会在界面上诱发大量几何必要位错的积累,导致应变分布和异变形诱导应力(HDI)积累,从而极大地促进了 HDI 的强化。HDI 强化、沉淀强化和晶界强化是 MEA 产生超高屈服强度的主要机制。在变形过程中,主要的变形机制包括位错滑移、变形引起的堆积断层和 Lomer-Cottrell 锁,以及轻微的变形孪生。这些多种变形模式的协同作用使 MEA 具有出色的加工硬化能力,延缓了塑性不稳定性,实现了强度和延展性的完美结合。这项研究通过将高密度互联强化与传统强化机制相结合,提供了一种协同强化 MEA 的有效策略。这些发现为开发高性能的先进结构材料铺平了道路,使其能够满足工程领域的苛刻应用要求。
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Pursuing ultrahigh strength–ductility CoCrNi-based medium-entropy alloy by low-temperature pre-aging
Developing high-performance alloys with gigapascal strength and excellent ductility is crucial for modern engineering applications. The concept of multi-component high/medium entropy alloys (H/MEAs) provides an innovative approach to designing such alloys. In this work, we developed the Co1.5CrNi1.5Al0.2Ti0.2 MEA, which exhibits outstanding mechanical properties at room temperature through low-temperature pre-aging followed by annealing treatment. Tensile testing reveals that the MEA possesses an ultrahigh yield strength of 20±0785 MPa, an ultimate tensile strength of 2365 ± 70 MPa, and exceptional ductility of 15.8% ±1.7%. The superior tensile properties are attributed to the formation of fully recrystallized heterogeneous structures (HGS) composed of ultrafine grain (UFG) and fine grain (FG) regions, along with discontinuous precipitation of coherent nano-size lamellar L12 precipitates. The mechanical incompatibility between the UFG region and the FG regions during deformation induces the accumulation of a large number of geometrically necessary dislocations at the interface, resulting in strain distribution and hetero-deformation-induced (HDI) stress accumulation, contributing significantly to HDI strengthening. HDI strengthening, precipitation strengthening, and grain boundary strengthening are the primary mechanisms responsible for the ultra-high yield strength of the MEA. During deformation, the dominant deformation mechanisms include dislocation slip, deformation-induced stacking faults, and Lomer–Cottrell locks, with minor deformation twinning. The synergistic interaction of these multiple deformation modes provides the MEA with excellent work hardening capability, delaying plastic instability and achieving an excellent combination of strength and ductility. This study provides an effective strategy for synergistically strengthening MEAs by combining HDI strengthening with traditional strengthening mechanisms. These findings pave the way for the development of advanced structural materials with high performance tailored for demanding applications in engineering.
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来源期刊
Journal of Materials Science & Technology
Journal of Materials Science & Technology 工程技术-材料科学:综合
CiteScore
20.00
自引率
11.00%
发文量
995
审稿时长
13 days
期刊介绍: Journal of Materials Science & Technology strives to promote global collaboration in the field of materials science and technology. It primarily publishes original research papers, invited review articles, letters, research notes, and summaries of scientific achievements. The journal covers a wide range of materials science and technology topics, including metallic materials, inorganic nonmetallic materials, and composite materials.
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