Numerical Study of the Correspondence Between the Dissipative and Fixed Energy Abelian Sandpile Models
arXiv:1104.3548 · doi:10.1103/PhysRevE.84.066119
Abstract
We consider the Abelian sandpile model (ASM) on the large square lattice with a single dissipative site (sink). Particles are added by one per unit time at random sites and the resulting density of particles is calculated as a function of time. We observe different scenarios of evolution depending on the value of initial uniform density (height) $h_0=0,1,2,3$. During the first stage of the evolution, the density of particles increases linearly. Reaching a critical density $Ï_c(h_0)$, the system changes its behavior sharply and relaxes exponentially to the stationary state of the ASM with $Ï_s=25/8$. We found numerically that $Ï_c(0)=Ï_s$ and $Ï_c(h_0>0) \neq Ï_s$. Our observations suggest that the equality $Ï_c=Ï_s$ holds for more general initial conditions with non-positive heights. In parallel with the ASM, we consider the conservative fixed-energy Abelian sandpile model (FES). The extensive Monte-Carlo simulations for $h_0=0,1,2,3$ have confirmed that in the limit of large lattices $Ï_c(h_0)$ coincides with the threshold density $Ï_{th}(h_0)$ of FES. Therefore, $Ï_{th}(h_0)$ can be identified with $Ï_s$ if the FES starts its evolution with non-positive uniform height $h_0 \leq 0$.
6 pages, 8 figures