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Atomic cluster dynamics causes intermittent aging of metallic glasses
Summary
Researchers used computer simulations to investigate why metallic glasses age in an intermittent, stop-and-start pattern rather than gradually slowing down over time. They found that this behavior is driven by sudden collective rearrangements of small clusters of atoms within the material. The study provides new insights into the fundamental physics of how glassy materials change their structure over time.
In the past two decades, numerous relaxation or physical aging experiments of metallic glasses have revealed signatures of intermittent atomic-scale processes. Revealed via intensity cross-correlations from coherent scattering using x-ray photon correlation spectroscopy (XPCS), the observed abrupt changes in the time-domain of atomic motion does not fit the picture of gradual slowing down of relaxation times and their origin continues to remain unclear. Using a binary Lennard-Jones model glass subjected to microsecond-long isotherms, we show here that temporal and spatially heterogeneous atomic-cluster activity at different length-scales drive the emergence of highly non-monotonous intensity cross-correlations. The simulated XPCS experiments reveal a variety of time-dependent intensity-cross correlations that, depending on both the structural evolution and the q-space sampling, give detailed insights into the possible structural origins of intermittent aging measured with XPCS.
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