Microscopic processes controlling the Herschel-Bulkley exponent
arXiv:1708.00516 · doi:10.1103/PhysRevE.97.012603
Abstract
The flow curve of various yield stress materials is singular as the strain rate vanishes, and can be characterized by the so-called Herschel-Bulkley exponent $n=1/β$. A mean-field approximation due to Hebraud and Lequeux (HL) assumes mechanical noise to be Gaussian, and leads to $β=2$ in rather good agreement with observations. Here we prove that the improved mean-field model where the mechanical noise has fat tails instead leads to $β=1$ with logarithmic correction. This result supports that HL is not a suitable explanation for the value of $β$, which is instead significantly affected by finite dimensional effects. From considerations on elasto-plastic models and on the limitation of speed at which avalanches of plasticity can propagate, we argue that $β=1+1/(d-d_f)$ where $d_f$ is the fractal dimension of avalanches and $d$ the spatial dimension. Measurements of $d_f$ then supports that $β\approx 2.1$ and $β\approx 1.7$ in two and three dimensions respectively. We discuss theoretical arguments leading to approximations of $β$ in finite dimensions.
9 pages, 3 figures