Bifurcation of the Kirkendall marker plane and the role of Ni and other impurities on the growth of Kirkendall voids in the Cu Sn system

TL;DR

This study investigates the bifurcation of the Kirkendall marker plane in the Cu-Sn system, revealing how impurities and diffusion rates influence void growth and challenging previous assumptions about void formation locations.

Contribution

It provides the first microstructural detection of bifurcated Kirkendall marker planes and links impurity levels to void growth mechanisms in Cu-Sn alloys.

Findings

Bifurcation of the Kirkendall marker plane confirmed via SEM and TEM.

Impurities above 0.1 wt% significantly increase void growth.

Void growth occurs on both sides of the newly identified Kirkendall marker plane.

Abstract

The presence of bifurcation of the Kirkendall marker plane, a very special phenomenon discovered recently, is found in a technologically important Cu Sn system. It was predicted based on estimated diffusion coefficients; however, could not be detected following the conventional inert marker experiments. As reported in this study, we could detect the locations of these planes based on the microstructural features examined in SEM and TEM. This strengthens the concept of the physicochemical approach that relates microstructural evolution with the diffusion rates of components and imparts finer understanding of the growth mechanism of phases. The estimated diffusion coefficients at the Kirkendall marker planes indicates that the reason for the growth of the Kirkendall voids is the nonconsumption of excess vacancies which are generated due to unequal diffusion rate of components. Systematic experiments using different purity of Cu in this study indicates the importance of the presence of impurities on the growth of voids, which increases drastically for greather than 0.1 wt percent impurity. The growth of voids increases drastically for electroplated Cu, commercially pure Cu and Cu(0.5 at percent Ni) indicating the adverse role of both inorganic and organic impurities. Void size and number distribution analysis indicates the nucleation of new voids along with the growth of existing voids with the increase in annealing time. The newly found location of the Kirkendall marker plane in the Cu3Sn phase indicates that voids grow on both the sides of this plane which was not considered earlier for developing theoretical models.