English

Understanding the volume-diffusion governed shape-instabilities in metallic systems

Materials Science 2019-06-26 v1

Abstract

The reliability of any day-to-day material is critically dictated by its properties. One factor which governs the behaviour of a material, under a given condition, is the microstructure. Despite the absence of any phase transformation, a change in the microstructure would significantly alter the properties. Therefore, a substantial understanding on the stability of the microstructure is vital to avert any unexpected catastrophic change in the material properties. In the present work, one such numerical approach called phase-field modelling in employed to analyse the stability of two- and three-dimensional finite structures, which dictate the curvature-driven evolution of the microstructure. A characteristic feature of this numerical approach is the introduction of a scalar variable, called the phase field, in addition to the other thermodynamic variables. While the inclusion of the phase field obviates the need for the interface tracking, which is a strenuous aspect of the other conventional techniques, it replaces the sharp interface with a finite diffuse region. Therefore, before adopting and extending the phase-field technique, it is shown that the model recovers the governing law, i.e, Gibbs-Thomson relation, despite the introduction of the diffuse interface. Subsequently, the numerical treatment is employed to investigate the volume-diffusion governed curvature-induced transformation.

Keywords

Cite

@article{arxiv.1906.10404,
  title  = {Understanding the volume-diffusion governed shape-instabilities in metallic systems},
  author = {P G Kubendran Amos},
  journal= {arXiv preprint arXiv:1906.10404},
  year   = {2019}
}
R2 v1 2026-06-23T10:02:49.047Z