We used speckle visibility spectroscopy to measure the time-resolved dynamcis of avalanching down the inclined surface of a granular material in a half-full rotating drum operating in the slumping regime. The distribution of the avalanche period, $t_d$, rest time between them, $t_r$, and peak particle velocity fluctuation, $\delta v_p^2$, are all normally distributed. While the distributions of the two times at the top and bottom of the free surface are very similar, the particle velocity fluctuation is greater at the bottom of the free surface than at the top. The rest time is observed to be inversely related to the drum speed. Combining this with the relation of $t_r$ and the difference of the upper and lower angle of repose for the granular material, $\Delta \theta$, we find that the latter decreases linearly with increasing rotational speed. We also observe that $t_d$ increases in a linear fashion with the drum speed. Using the relation of $t_r$ and the distance that particles have to move during an avalanche, we further find that a new scaling relation of the mean number of avalanches required to traverse the free surface with drum speed. We find that the slumping frequency increases with the rotating speed before becoming constant in the slumping-to-rolling transition region. Finally, we find that the average peak of the fluctuation speed of the avalanche, $\delta v_p^2$, increases linearly with the drum speed.

• Received 9 December 2014

DOI:https://doi.org/10.1103/PhysRevE.91.042206