English

Constructing phase diagrams for defects by correlated atomic-scale characterization

Materials Science 2023-09-01 v2

Abstract

Phase transformations and crystallographic defects are two essential tools to drive innovations in materials. Bulk materials design via tuning chemical compositions has been systematized using phase diagrams. We show here that the same thermodynamic concept can be applied to understand the chemistry at defects. We present a combined experimental and modelling approach to scope and build phase diagrams for defects. The discovery was enabled by triggering phase transformations of individual defects through local alloying, and sequentially imaging the structural and chemical changes using atomic-resolution scanning transmission electron microscopy. By observing atomic-scale phase transformations of a Mg grain boundary through Ga alloying, we exemplified the method to construct a grain boundary phase diagram using ab initio simulations and thermodynamic principles. The methodology enables a systematic development of defect phase diagrams to propel a new paradigm for materials design utilizing chemical complexity and phase transformations at defects.

Keywords

Cite

@article{arxiv.2303.09465,
  title  = {Constructing phase diagrams for defects by correlated atomic-scale characterization},
  author = {Xuyang Zhou and Prince Mathews and Benjamin Berkels and Saba Ahmad and Amel Shamseldeen Ali Alhassan and Philipp Keuter and Jochen M. Schneider and Dierk Raabe and Jörg Neugebauer and Gerhard Dehm and Tilmann Hickel and Christina Scheu and Siyuan Zhang},
  journal= {arXiv preprint arXiv:2303.09465},
  year   = {2023}
}
R2 v1 2026-06-28T09:20:24.875Z