A locally preferred structure characterises all dynamical regimes of a supercooled liquid

Abstract

Recent experimental results suggest that metallic liquids universally exhibit a high-temperature dynamical crossover, which is correlated with the glass transition temperature (Tg). We demonstrate, using molecular dynamics results for Cu64Zr36, that this temperature, TA ≈ 2 × Tg, is linked with cooperative atomic rearrangements that produce domains of connected icosahedra. Supercooling to a new characteristic temperature, TD, is shown to produce higher order cooperative rearrangements amongst connected icosahedra, leading to large-scale domain fluctuations and the onset of glassy dynamics. These extensive domains then abruptly stabilize above Tg and eventually percolate before the glass is formed. All characteristic temperatures (TA, TD and Tg) are thus connected by successive manifestations of the structural cooperativity that begins at TA.