310不锈钢薄晶中纳米裂纹形核和钝性的现场观察

Q.-Z. Chen, W.-Y. Chu, Y.-B. Wang, C.-M. Hsiao
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引用次数: 52

摘要

采用透射电镜(TEM)对310不锈钢薄晶进行了原位拉伸试验,研究了纳米裂纹的成核和钝性。位错释放刚停止后,可形成位错无区。裂缝区是一个弹性区,裂缝尖端附近的局部应力可能达到内聚强度,因此可能在裂缝区或裂缝尖端产生纳米裂纹。在一定位移条件下,塑性区或裂纹尖端的纳米裂纹也会随着位错的增加和移动而钝化成空洞或缺口。如果长时间保持恒定的位移,纳米空洞可以通过过饱和空位的扩散和富集在DFZ中形成。纳米孔隙的连接将导致纳米裂纹的产生。
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In situtem observations of nucleation and bluntness of nanocracks in thin crystals of 310 stainless steel

Nucleation and bluntness of nanocracks were studied through in situ tensile tests for thin crystals of 310 stainless steel by transmission electron microscopy (TEM). A dislocation free zone (DFZ) could form after the dislocation emission had just ceased. The DFZ is an elastic zone so that the local stress near the crack tip in the DFZ is possibly up to the cohesive strength, because of which a nanocrack could initiate in the DFZ or at the crack tip. The nanocrack in the DFZ or at the crack tip would blunt into a void or a notch through the increment and movement of dislocations in the plastic zone even when keeping constant displacement. If constant displacement was kept for a long time, nanovoids could initiate in the DFZ through diffusion and enrichment of supersaturation vacancies. The connection of the nanovoids would result in the initiation of nanocracks.

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