On the interplay of liquid-like and stress-driven dynamics in a metallic glass former observed by temperature scanning XPCS
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Modern detector technology and highly brilliant fourth-generation synchrotrons allow to improve the temporal resolution in time-resolved diffraction studies. Profiting from this, we applied temperature scanning X-ray photon correlation spectroscopy (XPCS) to probe the dynamics of a Pt-based metallic glass former in the glass, glass transition region, and supercooled liquid, covering up to six orders of magnitude in time scales. Our data demonstrates that the structural alpha-relaxation process is still observable in the glass, although it is partially masked by a faster source of decorrelation observed at atomic scale. We present an approach that interprets these findings as the superposition of heterogeneous liquid-like and stress-driven ballistic-like atomic motions. This work not only extends the dynamical range probed by standard isothermal XPCS, but also clarifies the fate of the alpha-relaxation across the glass transition and provides a new perception on the anomalous, compressed temporal decay of the density-density correlation functions observed in metallic glasses and many out-of-equilibrium soft materials.
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Cited by 2 Pith papers
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Non-Maxwellian Velocity Statistics in Supercooled Liquids and Their Possible Relation to Super-Arrhenius Viscosity
Supercooled liquids exhibit persistent non-Maxwellian velocity distributions with excess kurtosis 0<κ≲0.3 linked via temperature fluctuation width A_bar≈0.08 to super-Arrhenius viscosity across 45 glass formers.
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Non-Maxwellian Velocity Statistics in Supercooled Liquids and Their Possible Relation to Super-Arrhenius Viscosity
Supercooled liquids exhibit persistent non-Maxwellian velocity distributions with excess kurtosis linked to temperature fluctuation width A-bar ~0.08, consistent with viscosity data collapse across 45 glass formers.
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