What question did this study set out to answer?

This research aims to explore the statistical properties of thermal avalanches in driven amorphous materials.

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April 10, 2026

Statistics of thermal avalanches in driven amorphous systems

Key Points

This research aims to explore the statistical properties of thermal avalanches in driven amorphous materials.
Utilized random first-order transition theory of glasses.
Analyzed waiting-time statistics of thermal avalanches.
Employed a generalized master equation to capture aging dynamics.
Applied the framework under quasi-static shear and stochastic shaking protocols.
Derived the complete distribution of avalanche magnitudes and counts.
Findings reveal non-Poisson waiting-time statistics for thermal avalanches.
Identified non-Markovian dynamics in avalanche clusters.
Characterized intermediate-time behavior in avalanche magnitudes and counts.
Observed distinct nonequilibrium signatures in effective temperatures and auto-correlation functions.

Abstract

Within the framework of the random first-order transition theory of glasses, we discuss the statistics of "thermal avalanches," the large scale rearrangements in driven amorphous systems near their instability. Stringy excitations yield non-Poisson waiting-time statistics. Embedding these statistics in a generalized master equation captures the non-Markovian, aging dynamics of avalanche clusters. We apply this framework to analyze nonequilibrium signatures of thermal avalanches-auto-correlation functions and effective temperatures-under both quasi-static shear and stochastic shaking protocols. We use full counting statistics to derive the complete distribution of both the avalanche magnitudes and avalanche counts, uncovering the intermediate-time behavior.

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Statistics of thermal avalanches in driven amorphous systems

Key Points

Abstract

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