Effect of second-phase precipitates on deformation microstructure in AA2024 (Al–Cu–Mg): dislocation substructures and stored energy

IF 3.5 3区 材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Daniel Irmer, Can Yildirim, Mohamed Sennour, Vladimir A. Esin, Charbel Moussa
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Abstract

The importance of comprehensive multiscale characterisation in advancing our understanding of engineering materials is undeniable but remains a challenging pursuit. Combining complimentary microstructure characterisation techniques, including transmission electron microscopy, electron backscatter diffraction and dark-field X-ray microscopy (DFXM), the formation of deformation microstructures is investigated in presence of shearable and non-shearable hardening precipitates in an industrial aluminium alloy (AA) 2024 (Al–Cu–Mg family). The alloy was used in naturally aged T3 (with shearable co-clusters and Guinier–Preston–Bagaryatsky (GPB) zones) and peak-hardened T8 (with non-shearable S-phase precipitates) states. After cold rolling with thickness reductions varying from 25 to 60% (or corresponding von Mises strain from 0.33 to 1.06), the T8 state revealed a higher sub-boundary density with slightly smaller mean disorientation angle, as compared to those in the T3 state. At a von Mises strain of 0.33, the T8 state exhibited higher long-range orientation gradients, as compared to the T3 state, for higher strain orientation gradients in T3 surpass those in T8 state. With DFXM, distinct 3D substructures are shown, revealing ellipsoidal sub-grains in the T8 state and pancake-like sub-grains in the T3 state. Moreover, the stored energy induced by cold rolling is higher for the T8 state. These results indicate different deformation microstructures, formed in the same AA2024 but hardened by shearable and non-shearable precipitates.

第二相析出物对 AA2024(铝-铜-镁)变形微观结构的影响:位错亚结构和储能
全面的多尺度表征对于加深我们对工程材料的理解具有不可否认的重要意义,但仍然是一项具有挑战性的工作。本研究结合透射电子显微镜、电子反向散射衍射和暗场 X 射线显微镜 (DFXM) 等微结构表征技术,研究了工业铝合金 (AA) 2024(Al-Cu-Mg 家族)中可剪切和不可剪切硬化析出物的变形微结构的形成。合金在自然时效 T3(具有可剪切共簇和 Guinier-Preston-Bagaryatsky (GPB) 区)和峰值硬化 T8(具有不可剪切 S 相析出物)状态下使用。冷轧厚度减薄 25% 至 60%(或相应的 von Mises 应变 0.33 至 1.06)后,与 T3 状态相比,T8 状态显示出更高的亚边界密度和稍小的平均取向角。当冯-米塞斯应变为 0.33 时,与 T3 状态相比,T8 状态显示出更高的长程取向梯度,因为 T3 状态中的高应变取向梯度超过了 T8 状态中的高应变取向梯度。通过 DFXM,可以看到不同的三维亚结构,在 T8 状态下显示出椭圆形亚晶粒,而在 T3 状态下显示出薄饼状亚晶粒。此外,T8 状态下冷轧引起的储能更高。这些结果表明,在相同的 AA2024 中,由可剪切和不可剪切析出物硬化形成了不同的变形微观结构。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Materials Science
Journal of Materials Science 工程技术-材料科学:综合
CiteScore
7.90
自引率
4.40%
发文量
1297
审稿时长
2.4 months
期刊介绍: The Journal of Materials Science publishes reviews, full-length papers, and short Communications recording original research results on, or techniques for studying the relationship between structure, properties, and uses of materials. The subjects are seen from international and interdisciplinary perspectives covering areas including metals, ceramics, glasses, polymers, electrical materials, composite materials, fibers, nanostructured materials, nanocomposites, and biological and biomedical materials. The Journal of Materials Science is now firmly established as the leading source of primary communication for scientists investigating the structure and properties of all engineering materials.
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