Oscillatory quasistatic shear deformation of amorphous materials: a mesoscopic approach

Recent atomistic simulations have identified novel rheological properties on amorphous materials under quasi-static oscillatory shear. Using a coarse-grained model based on the evolution of a continuum strain field we characterize these properties in the stationary limit, reached after several oscillations. We built a `phase diagram' depending on two control parameters: the strain amplitude $\gamma_{\max}$ and the degree of annealing $E_{\text{init}}$. At small amplitudes, poorly annealed materials display {\it shear annealing} behavior, appearing better and better annealed as $\gamma_{\max}$ is increased. Ultra-stable materials are instead insensitive to those oscillations. Above a critical strain amplitude $\gamma_c$, that increases with annealing level, the melting of the material in a localized band of finite width is observed. Inside the band, the material flows, outside the band there is a marginal solid independent of the initial degree of annealing. Such a `phase transition' at $\gamma_c$ between a solid and a mixed phase is discontinuous. The transient dynamics before reaching the steady state is also studied.