InSb晶体弯曲变形中的极性:II。理论与辅助实验(物理)

Science reports of the Research Institutes, Tohoku University. Ser. A, Physics, chemistry and metallurgy Pub Date : 1975-07-01 DOI:10.1080/14786437508222811

K. Sumino, H. Shimizu

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引用次数: 15

摘要

对具有闪锌矿结构的弯曲晶体中{111}四面体的几何形态进行了研究，结果表明，弯曲类型在主要滑移面和某些次要滑移面之间是相反的。这就解释了为什么次级滑动被激活，而初级滑动面在β弯曲中变得富含森林。两种类型的实验建立了β-弯曲比α-弯曲更高的流动应力的来源。结果表明:低屈服点后变形阶段两种弯曲的流变应力差异主要源于次级滑移体系活动性的差异，而变形早期则是由于α-位错与β-位错在初级滑移面上的迁移率不同导致螺位错密度的增加速率差异。

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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Polarity in Bending Deformation in InSb Crystals : II. Theory and Supplementary Experiments(Physics)

Abstract A geometrical consideration of the configuration of {111} tetrahedra in a bent crystal having the sphalerite structure shows that the type of bending is reversed between the primary slip plane and some of the secondary slip planes. This explains why the secondary slip is activated and the primary slip plane becomes forest-rich in β-bending. Two types of experiments establish the origin of the higher flow stress in β-bending compared with α-bending. It is concluded that the difference in the flow stress between the two types of bending in the deformation stage after the lower yield point originates mainly from the difference in the activity of the secondary slip system, while that in the early stage of deformation originates from the difference in the rate of increase in the density of screw dislocations due to the difference in the mobility between α-dislocations and β-dislocations moving on the primary slip plane.

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Science reports of the Research Institutes, Tohoku University. Ser. A, Physics, chemistry and metallurgy

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