Achieving excellent uniform tensile ductility and strength in dislocation-cell-structured high-entropy alloys

IF 9.4 1区 材料科学 Q1 ENGINEERING, MECHANICAL
Rui Huang , Lingkun Zhang , Abdukadir Amar , Peter K. Liaw , Tongmin Wang , Tingju Li , Yiping Lu
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Abstract

Body-centered-cubic (BCC) high-entropy alloys (HEAs) encounter significant challenges in obtaining a high uniform tensile ductility (UTD). A dense dislocation-cell (DC) structure is produced in a heterogeneously grained HEA under tensile deformation, resulting from the anchored dislocation motion by grain interior elemental segregation. This fluctuation in elemental concentration is facilitated by thermomechanical processing. The activation of multiple-slip mechanisms, prompted by strain incompatibility among grains of varying sizes, significantly propels this process forward. This novel DC structure simultaneously increased the UTD (by 349.1 %) and yield strength (σ0.2, by 29.0 %) for a stable BCC HEA. Specifically, the single-phase alloy achieved a record-high UTD of 7.5 % and an σ0.2 of > 1,200 MPa, outperforming the counterparts of all the single-phase BCC HEAs. We employed a combination of transmission electron microscopy, in-situ scanning electron microscopy tensile testing coupled with an electron backscatter diffraction technology to investigate underlying strengthening mechanisms and identified that the serious stress concentration as a result of prevalent planar slip caused premature failure and localized strain of common BCC HEAs. At the initial stage of deformation, the DC structure promoted the activation of multiple slip systems and facilitated the extension of a plastic flow across the sample volume, effectively weakening stress concentration and premature failure. The extended plasticity zone and intensified dislocation interactions contributed to the increased UTD and σ0.2. These findings offer valuable inspiration for tailoring alloy properties via microstructure strategies and promoting their adoption in advanced manufacturing.

Abstract Image

在位错电池结构高熵合金中实现优异的均匀拉伸延展性和强度
体心立方(BCC)高熵合金(HEAs)在获得高均匀拉伸延展性(UTD)方面面临重大挑战。在拉伸变形过程中,异质晶粒 HEA 中会产生密集的位错胞(DC)结构,这是晶粒内部元素偏析导致的锚定位错运动造成的。热机械加工促进了元素浓度的波动。不同尺寸晶粒之间的应变不相容性导致的多重滑移机制的启动,极大地推动了这一过程。这种新型直流结构同时提高了稳定 BCC HEA 的UTD(349.1%)和屈服强度(29.0%)。具体来说,这种单相合金的UTD达到了创纪录的7.5%,屈服强度大于1200兆帕,优于所有单相BCC HEA。我们采用透射电子显微镜、原位扫描电子显微镜拉伸测试与电子反向散射衍射技术相结合的方法来研究潜在的强化机制,并发现由于普遍存在的平面滑移导致严重的应力集中,从而造成普通 BCC HEA 的过早失效和局部应变。在变形的初始阶段,直流结构促进了多重滑移系统的激活,促进了塑性流动在样品体积上的扩展,有效削弱了应力集中和过早失效。塑性区的扩展和位错相互作用的加强导致了UTD和.DC的增加。这些发现为通过微结构策略定制合金特性并促进其在先进制造业中的应用提供了宝贵的启示。
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来源期刊
International Journal of Plasticity
International Journal of Plasticity 工程技术-材料科学:综合
CiteScore
15.30
自引率
26.50%
发文量
256
审稿时长
46 days
期刊介绍: International Journal of Plasticity aims to present original research encompassing all facets of plastic deformation, damage, and fracture behavior in both isotropic and anisotropic solids. This includes exploring the thermodynamics of plasticity and fracture, continuum theory, and macroscopic as well as microscopic phenomena. Topics of interest span the plastic behavior of single crystals and polycrystalline metals, ceramics, rocks, soils, composites, nanocrystalline and microelectronics materials, shape memory alloys, ferroelectric ceramics, thin films, and polymers. Additionally, the journal covers plasticity aspects of failure and fracture mechanics. Contributions involving significant experimental, numerical, or theoretical advancements that enhance the understanding of the plastic behavior of solids are particularly valued. Papers addressing the modeling of finite nonlinear elastic deformation, bearing similarities to the modeling of plastic deformation, are also welcomed.
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