# Chemical-disorder-caused Medium Range Order in Covalent Glass

**Authors:** Xianqiang Liu, Xianbin Li, Xinyang Wang, Yongqiang Cheng, Xuepeng, Wang, Xiaodong Han, Ze Zhang, Shengbai Zhang

arXiv: 1703.04236 · 2017-03-14

## TL;DR

This study reveals that chemical disorder in covalent glasses like a-GeTe induces medium-range order through a novel atomic packing scheme, challenging traditional views and suggesting a universal mechanism for disordered covalent networks.

## Contribution

It uncovers a new atomic packing scheme explaining medium-range order in chemically disordered covalent glasses, supported by ab-initio calculations and experiments.

## Key findings

- Chemical disorder can induce medium-range order in covalent glasses.
- Homopolar bond chains form polyhedral clusters explaining MRO.
- The electron-counting model explains homopolar bond formation.

## Abstract

How atoms in covalent solids rearrange over a medium-range length-scale during amorphization is a long pursued question whose answer could profoundly shape our understanding on amorphous (a-) networks. Based on ab-intio calculations and reverse Monte Carlo simulations of experiments, we surprisingly find that even though the severe chemical disorder in a-GeTe undermined the prevailing medium range order (MRO) picture, it is responsible for the experimentally observed MRO. That this thing could happen depends on a novel atomic packing scheme. And this scheme results in a kind of homopolar bond chain-like polyhedral clusters. Within this scheme, the formation of homopolar bonds can be well explained by an electron-counting model and further validated by quantitative bond energy analysis based. Our study suggests that the underlying physics for chemical disorder in a-GeTe is intrinsic and universal to all severely chemically disordered covalent glasses.

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Source: https://tomesphere.com/paper/1703.04236