Resolving localized geometrically necessary dislocation densities in Al-Mg polycrystal via in situ EBSD

IF 5.4 2区医学 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Biomaterials Science & Engineering Pub Date : 2024-08-15 DOI:10.1016/j.actamat.2024.120290

Hongru Zhong , Qiwei Shi , Chengyi Dan , Xiaojiao You , Shuwei Zong , Shengyi Zhong , Yudong Zhang , Haowei Wang , Zhe Chen

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Abstract

The distribution of geometrically necessary dislocation (GND) densities is critical to understanding the heterogeneous plastic deformation at intragranular scales in polycrystals. In this work, we performed an in situ electron backscatter diffraction (EBSD) measurement during the tensile test on a polycrystalline Al-Mg alloy. The EBSD patterns were processed through the integrated digital image correlation algorithm to enhance angular resolution. Based on the Nye dislocation density tensor, GND densities of 18 dislocation types in fcc crystals were resolved and mapped at macroscopic strains ranging from 5% to 16%. The evolution of GND distribution showed that GNDs were generated near grain boundaries at small strains and later localized at grain interiors along subgrain boundaries and slip bands at large strains. The inhomogeneous increase in GND densities of different dislocation types, representing dislocation substructures, along the subgrain boundaries was disclosed. Meanwhile, high GND densities were observed along the slip bands when a double noncoplanar slip system was activated inside the grains. The obstructed movement of dislocations by Lomer junctions explained the GND storage in different ${111}$ slip planes. The existence of Lomer junctions was proven by Burgers circuit analysis with high-resolution transmission electron microscopy, which explained the increase in $[101]$ screw dislocation density according to the dislocation reaction.

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通过原位 EBSD 解决铝镁多晶体中的局部几何必要位错密度问题

几何必要位错（GND）密度的分布对于理解多晶体晶内尺度的异质塑性变形至关重要。在这项工作中，我们在对多晶铝镁合金进行拉伸试验时进行了原位电子反向散射衍射（EBSD）测量。EBSD 图样通过集成数字图像相关算法进行处理，以提高角度分辨率。根据奈伊位错密度张量，在 5% 至 16% 的宏观应变范围内，分辨并绘制了 fcc 晶体中 18 种位错类型的 GND 密度。GND分布的演变表明，小应变时，GND在晶粒边界附近产生；大应变时，GND沿着亚晶粒边界和滑移带在晶粒内部定位。不同类型位错的 GND 密度沿亚晶粒边界不均匀地增加，代表了位错亚结构。同时，当晶粒内部的双非共面滑移系统被激活时，沿滑移带也观察到了较高的 GND 密度。位错运动受到 Lomer 连接的阻碍，解释了 GND 储存在不同 {111} 滑移面的原因。利用高分辨率透射电子显微镜进行的伯格斯电路分析证明了 Lomer 连接的存在，并根据位错反应解释了 [101] 螺旋位错密度的增加。

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来源期刊

ACS Biomaterials Science & Engineering Materials Science-Biomaterials

CiteScore

10.30

自引率

3.40%

发文量

413

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