Nature Communications (May 2024)

Revealing the hidden structure of disordered materials by parameterizing their local structural manifold

  • Thomas J. Hardin,
  • Michael Chandross,
  • Rahul Meena,
  • Spencer Fajardo,
  • Dimitris Giovanis,
  • Ioannis Kevrekidis,
  • Michael L. Falk,
  • Michael D. Shields

DOI
https://doi.org/10.1038/s41467-024-48449-0
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 11

Abstract

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Abstract Durable interest in developing a framework for the detailed structure of glassy materials has produced numerous structural descriptors that trade off between general applicability and interpretability. However, none approach the combination of simplicity and wide-ranging predictive power of the lattice-grain-defect framework for crystalline materials. Working from the hypothesis that the local atomic environments of a glassy material are constrained by enthalpy minimization to a low-dimensional manifold in atomic coordinate space, we develop a generalized distance function, the Gaussian Integral Inner Product (GIIP) distance, in connection with agglomerative clustering and diffusion maps, to parameterize that manifold. Applying this approach to a two-dimensional model crystal and a three-dimensional binary model metallic glass results in parameters interpretable as coordination number, composition, volumetric strain, and local symmetry. In particular, we show that a more slowly quenched glass has a higher degree of local tetrahedral symmetry at the expense of cyclic symmetry. While these descriptors require post-hoc interpretation, they minimize bias rooted in crystalline materials science and illuminate a range of structural trends that might otherwise be missed.