Litcius/Paper detail

Thermally activated flow in models of amorphous solids

Marko Popović, Tom W. J. de Geus, Wencheng Ji, Matthieu Wyart

2021Physical review. E23 citationsDOIOpen Access PDF

Abstract

Amorphous solids yield at a critical value Σ_{c} of the imposed stress Σ through a dynamical phase transition. While sharp in athermal systems, the presence of thermal fluctuations leads to the rounding of the transition and thermally activated flow even below Σ_{c}. Here we study the steady-state thermal flow of amorphous solids using a mesoscopic elastoplastic model. In the Hébraud-Lequex (HL) model we provide an analytical solution of the thermally activated flow at low temperature. We then propose a general scaling law that also describes the transition rounding. Finally, we find that the scaling law holds in numerical simulations of the HL model, a two-dimensional (2D) elastoplastic model, and previously published molecular dynamics simulations of 2D Lennard-Jones glass.

Topics & Concepts

RoundingMesoscopic physicsAmorphous solidScalingSigmaThermodynamicsGlass transitionFlow (mathematics)Materials scienceYield (engineering)Molecular dynamicsPhysicsStatistical physicsCondensed matter physicsMechanicsChemistryMathematicsCrystallographyQuantum mechanicsPolymerComputer scienceComposite materialGeometryOperating systemMaterial Dynamics and PropertiesTheoretical and Computational PhysicsLiquid Crystal Research Advancements