Temperature and driving rate effects on the yielding transition of amorphous solids

Abstract: (1154/1300)

The yielding transition in amorphous solids is well studied in the athermal and quasistatic (AQS) limit, where its jerky, avalanching flow is an exemplary realization of self-organized criticality. Crucially, the critical exponents of these avalanches present in quasistatic driving have been connected to the Herschel-Bulkley (HB) exponent that governs the macroscopic response of the material to high driving rates. Here, by equipping a mesoscale elastoplastic model (EPM) for amorphous plasticity with a temperature dependent yielding of weak sites, we investigate how the yielding transition is affected by temperature. We find that avalanche sizes can be truncated by either temperature or finite-size effects and derive a dynamic phase diagram capturing the onset of continuous flow as a function of temperature, driving rate, and system size [1]. We find that in the continuously flowing phase, the HB exponent transitions to a lower value when the temperature is high [1]. We present scaling arguments that connect the smaller temperature truncated avalanches to this high-temperature HB exponent and compare this to alterations in HB scaling found in a related mean-field model.

[1] D. Korchinski and J. Rottler, Dynamic Phase Diagram of Plastically Deformed Amorphous Solids at Finite Temperature, Phys. Rev. E 106, 034103 (2022).