论文信息 - First-principles Calculation on Screw Dislocation Core Properties in BCC Molybdenum

First-principles Calculation on Screw Dislocation Core Properties in BCC Molybdenum

Predicting atomistic properties of a dislocation is a first step toward an understanding of plastic behavior of materials, in particular BCC metals. The core structure and Peierls stress of a screw dislocation in BCC metals have been studied over the years using the first-principles and empirical methods, however, their conclusions vary due to the inefficiency of the methods. We have executed first-principles calculations based on the density functional method, employing the most accurate 1 · 1 · 20 k-point samplings, to determine the core structure and Peierls stress of the a0/2(111) screw dislocation of molybdenum. We have concluded that the core has a 6-fold structure, and determined the Peierls stress of 1.8 GPa for the simple shear strain along the (-110) direction.

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