Determination of the Radius of Triple Junctions of Tilt Boundaries: A Molecular Dynamics Simulation

Abstract

Using the method of molecular dynamics, an investigation of the free volume and energy distribution is performed in the region of triple junctions of high-angle tilt boundaries with the and misorientation axes in nickel formed as a result of recrystallization. Crystallization is simulated from three crystalline nuclei for the varied free volume value. It is shown that during recrystallization the free volume is mainly concentrated in the region of grain boundaries and its fraction increases on approaching the grain-boundary junction. From the effective energy distribution in the region of triple junctions, their effective radius is determined. In the tilt boundaries and their junctions, the free volume during recrystallization is dispersed more effectively that it is in the junctions formed by the boundaries. For this reason, the energy radius of the triple junction of the boundaries hardly varies with an introduction of a free volume: from 5 to 7 A, while that of the junction of the boundaries upon introduction of 2% vacancies into the initial computational cell becomes as large 14 A.