Precipitation strengthening in Cu–Ni–Si alloys modeled with <italic>ab initio</italic> based interatomic potentials.

Effective interaction potentials suitable for Cu/<italic>δ</italic>–Ni2Si and Cu/<italic>β</italic>–Ni3Si are developed. We optimise the potential parameters of an embedded atom method potential to reproduce forces, energies, and stresses obtained from <italic>ab initio</italic> calculations. Details of the potential generation are given, and its validation is demonstrated. The potentials are used in molecular dynamics simulations of shear tests to study the interactions of edge dislocations with coherent <italic>δ</italic>–Ni2Si and <italic>β</italic>–Ni3Si precipitates embedded in a copper matrix. In spite of significantly different crystallographic structures of copper and <italic>δ</italic>–Ni2Si which usually result in circumvention of dislocations, we also observed cutting processes in our simulations. Dislocations cut for a specific orientation of the <italic>δ</italic>–Ni2Si precipitate and in some cases where dislocation loops originating from previous circumvention processes are present in the glide plane. It is found that <italic>β</italic>–Ni3Si precipitates have a similar effect on precipitation strengthening as <italic>δ</italic>–Ni2Si. Dislocations usually cut <italic>β</italic>–Ni3Si but increased coherency strain can lead to circumvention processes. [ABSTRACT FROM AUTHOR]