温度高于流动应力峰值时Ni3Al滑动的几何形状

Acta Metallurgica Pub Date : 1989-12-01 DOI:10.1016/0001-6160(89)90195-8

P.M. Hazzledine , M.H. Yoo , Y.Q. Sun

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引用次数: 29

摘要

当温度高于Ni3Al流变应力峰值时，滑移体系< 110 >{001}。在较高的温度下，第二个系统< 010 >{001}也在工作。两种类型的位错都形成滑动环，这些滑动环解离成12个< 110 > apb连接的部分，两种滑动环都表现出弹性不稳定性。有三种类型的位错可以通过在{111}平面上的二次解离进一步降低它们的能量:螺旋< 110 >形成Kear-Wilsdorf锁，边缘< 110 >形成lomo - cottrell锁，45°< 010 >形成B5锁。< 110 >和< 010 >位错之间的相互作用产生了另外两种具有非平面核的位错，< 110 >锁和< 111 >锁。所有这些锁定位错都是缓慢移动或不移动的，除了< 111 >锁定外，所有这些锁定位错都可以在电子显微镜下观察到。< 110 >和< 111 >锁的形成以及两种滑移体系相互作用的混合，解释了Ni3Al中高温加工硬化峰的形成。

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The geometry of glide in Ni3Al at temperatures above the flow stress peak

At temperatures above the flow stress peak in Ni₃Al the slip system is 〈110〉{001}. At higher temperatures still a second system, 〈010〉{001}, also operates. Both types of dislocation form glide loops which dissociate into $12$ 〈110〉 APB-linked partials and both glide loops show ranges of elastic instability. Three types of dislocation may lower their energy further by a second dissociation on {111} planes: the screw 〈110〉 forms a Kear-Wilsdorf lock, the edge 〈110〉 forms a Lomer-Cottrell lock and the 45° 〈010〉 forms a B5 lock. Interactions between 〈110〉 and 〈010〉 dislocations give rise to two more dislocations with non-planar cores, the 〈110〉 lock and the 〈111〉 lock. All these locked dislocations are slow moving or immobile and all, except for the 〈111〉 lock, have been observed in the electron microscope. The formation of 〈110〉 and 〈111〉 locks and the mixing of the two slip systems through interactions between them give an explanation for the high-temperature work-hardening peak found in Ni₃Al.

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Acta Metallurgica

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