Vibration-induced "thermally activated" jamming transition in granular media
Abstract
The quasi-static frequency response of a granular medium is measured by a forced torsion oscillator method, with forcing frequency fp in the range 10-4 Hz to 5 Hz, while weak vibrations at high-frequency fs, in the range 50 Hz to 200 Hz, are generated by an external shaker. The intensity of vibration, , is below the fluidization limit. A loss factor peak is observed in the oscillator response as a function of or fp. In a plot of fp against 1/ , the position of the peak follows an Arrhenius-like behaviour over four orders of magnitude in fp. The data can be described as a stochastic hopping process involving a probability factor (-j/) with j a fs-dependent characteristic vibration intensity. A fs-independent description is given by (-τj/τ), with τj an intrinsic characteristic time, and τ = n/2π fs, n=0.5-0.6, an empirical control parameter with unit of time. τ is seen as the effective average time during which the perturbed grains can undergo structural rearrangement. The loss factor peak appears as a crossover in the dynamic behaviour of the vibrated granular system, which, at the time-scale 1/fp, is solid-like at low , and the oscillator is jammed into the granular material, and is fluid-like at high , where the oscillator can slide viscously.
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