Zhuan Ge, Teng Man, Kimberly M. Hill, Yujie Wang, Sergio Andres Galindo-Torres
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Jamming, Yielding, and Rheology during Submerged Granular Avalanche
Jamming transitions and the rheology of granular avalanches in fluids are
investigated using experiments and numerical simulations. Simulations use the
lattice-Boltzmann method coupled with the discrete element method, providing
detailed stress and deformation data. Both simulations and experiments present
a perfect match with each other in carefully conducted deposition experiments,
validating the simulation method. We analyze transient rheological laws and
jamming transitions using our recently introduced length-scale ratio $G$. $G$
serves as a unified metric for the pressure and shear rate capturing the
dynamics of sheared fluid-granular systems. Two key transition points, $G_{Y}$
and $G_{0}$, categorize the material's state into solid-like, creeping, and
fluid-like states. Yielding at $G_{Y}$ marks the transition from solid-like to
creeping, while $G_{0}$ signifies the shift to the fluid-like state. The
$\mu-G$ relationship converges towards the equilibrium $\mu_{eq}(G)$ after
$G>G_0$ showing the critical point where the established rheological laws for
steady states apply during transient conditions.