English

Predicting Complex Relaxation Processes in Metallic Glass

Materials Science 2019-09-09 v1

Abstract

Relaxation processes significantly influence the properties of glass materials. However, understanding their specific origins is difficult, even more challenging is to forecast them theoretically. In this study, using microseconds molecular dynamics simulations together with an accurate many-body interaction potential, we predict that an Al90_{\text{90}}Sm10_{\text{10}} metallic glass would have complex relaxation behaviors: In addition to the main (α\alpha) relaxation, the glass (i) shows a pronounced secondary (β\beta) relaxation at cryogenic temperatures and (ii) exhibits an anomalous relaxation process (α2\alpha_2) accompanying α\alpha relaxation. Both of the predictions are verified by experiments. Computational simulations reveal the microscopic origins of relaxation processes: while the pronounced β\beta relaxation is attributed to the abundance of string-like cooperative atomic rearrangements, the anomalous α2\alpha_2 process is found to correlate with the decoupling of the faster motions of Al with slower Sm atoms. The combination of simulations and experiments represents a first glimpse of what may become a predictive routine and integral step for glass physics.

Keywords

Cite

@article{arxiv.1909.03016,
  title  = {Predicting Complex Relaxation Processes in Metallic Glass},
  author = {Yang Sun and Si-Xu Peng and Qun Yang and Feng Zhang and Meng-Hao Yang and Cai-Zhuang Wang and Kai-Ming Ho and Hai-Bin Yu},
  journal= {arXiv preprint arXiv:1909.03016},
  year   = {2019}
}
R2 v1 2026-06-23T11:08:00.999Z