Spontaneous formation of permanent shear bands in a mesoscopic model of flowing disordered matter

TL;DR

This paper demonstrates that in a mesoscopic model of flowing disordered materials, permanent shear bands spontaneously form when the restructuring time exceeds a critical value, highlighting the importance of local dynamic timescales in shear band formation.

Contribution

It introduces a minimalistic mesoscopic model showing how large restructuring times lead to permanent shear bands, advancing understanding of flow heterogeneities in yield stress materials.

Findings

Permanent shear bands form when restructuring time is large.

Flow curve becomes non-monotonous for large restructuring times.

Homogeneous flow becomes unstable below a critical shear rate.

Abstract

This study proposes a coherent scenario of the formation of permanent shear bands in the flow of yield stress materials. It is a well accepted point of view that flow in disordered media is occurring via local plastic events, corresponding to small size rearrangements, that yield a long range stress redistribution over the system. Within a minimalistic mesoscopic model that incorporates these local dynamics, we study the spatial organisation of the local plastic events. The most important parameter in this study is the typical restructuring time needed to regain the original structure after a local rearrangement. In agreement with a recent mean field study [Coussot \textit{et al., Eur. Phys. J. E}, 2010, \textbf{33}, 183] we observe a spontaneous formation of permanent shear bands, when this restructuring time is large compared to the typical stress release time in a rearrangement. The bands consist of a large number of plastic events within a solid region that remains elastic. This heterogeneous flow behaviour is different in nature from the transient dynamical heterogeneities that one observes in the small shear rate limit in flow without shear-banding [Martens \textit{et al., Phys. Rev. Lett.}, 2011, \textbf{106}, 156001]. We analyse in detail the dependence of the shear bands on system size, shear rate and restructuring time. Further we rationalise the scenario within a mean field version of the spatial model, that produces a non monotonous flow curve for large restructuring times. This explains the instability of the homogeneous flow below a critical shear rate, that corresponds to the minimum of the curve. Our study therefore strongly supports the idea that the characteristic time scales involved in the local dynamics are at the physical origin of permanent shear bands.