Abstract
AbstractThe application of amorphous chalcogenide alloys as data‐storage media relies on their ability to undergo an extremely fast (10–100 ns) crystallization once heated at sufficiently high temperature. However, the peculiar features that make these materials so attractive for memory devices still lack a comprehensive microscopic understanding. By means of large scale molecular dynamics simulations, we demonstrate that the supercooled liquid of the prototypical compound GeTe shows a very high atomic mobility (D ∼10−6 cm2 s−1) down to temperatures close to the glass transition temperatures. This behavior leads to a breakdown of the Stokes–Einstein relation between the self‐diffusion coefficient and the viscosity in the supercooled liquid. The results suggest that the fragility of the supercooled liquid is the key to understand the fast crystallization process in this class of materials.
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