The relationship between slip behavior and dislocation arrangement for large-size Mo-3Nb single crystal at room temperature

The slip behavior and mechanism of large-size Mo-3Nb single crystal have been investigated and disclosed comprehensively at room temperature by quasi-static compression with various strains. With the increase of deformation, the slip traces change from shallow non-uniform slip lines to dense and uniform slip bands. Different slip traces in the same deformation condition were observed, suggesting that the slip traces in the single crystal are controlled by different types and arrangement mechanisms of mobile dislocation. To clarify the relationship between slip behavior and dislocation arrangement, TEM and AFM analyses were performed. Significant discrepancy between the mobility of screw segments and edge segments caused by double cross-slip multiplication mechanism is the reason why different slip features were witnessed. During the whole slip deformation process, screw dislocations play a dominant role and they are inclined to form wall-substructures by interaction and entanglement. With the development of dislocation accumulation, the entangled dislocation walls evolve into dislocation cells with higher stability. (c) 2021 Published by Elsevier Ltd on behalf of Chinese Society for Metals.

Automated summary

The slip behavior and mechanism of large-size Mo-3Nb single crystal at room temperature were investigated, revealing a transition from shallow non-uniform slip lines to dense and uniform slip bands with increased deformation. The disparities in mobility between screw segments and edge segments due to double cross-slip multiplication mechanism account for the observed different slip features. During slip deformation, screw dislocations dominate and tend to form wall-substructures, evolving into dislocation cells with higher stability through dislocation accumulation.