Inelastic collapse in one-dimensional driven systems under gravity

Abstract

We study the inelastic collapse in the one-dimensional N-particle systems in the situation where the system is driven from below under the gravity. We investigate the hard-sphere limit of the inelastic soft-sphere systems by numerical simulations to find how the collision rate per particle ncoll increases as a function of the elastic constant of the sphere k when the restitution coefficient e is kept constant. For the systems with large enough N 20, we find three regimes in e depending on the behavior of ncoll in the hard-sphere limit: (i) uncollapsing regime for 1 e > ec1, where ncoll converges to a finite value, (ii) logarithmically collapsing regime for ec1 > e > ec2, where ncoll diverges as ncoll k, and (iii) power-law collapsing regime for ec2 > e > 0, where ncoll diverges as ncoll kα with an exponent α that depends on N. The power-law collapsing regime shrinks as N decreases and seems not to exist for the system with N=3 while, for large N, the size of the uncollapsing and the logarithmically collapsing regime decreases as ec1 1-2.6/N and ec2 1-3.0/N. We demonstrate that this difference between large and small systems exists already in the inelastic collapse without the external drive and the gravity.