Condensation phenomena of conserved-mass aggregation model on weighted complex networks

Abstract

We investigate the condensation phase transitions of conserved-mass aggregation (CA) model on weighted scale-free networks (WSFNs). In WSFNs, the weight wij is assigned to the link between the nodes i and j. We consider the symmetric weight given as wij=(ki kj)α. In CA model, the mass mi on the randomly chosen node i diffuses to a linked neighbor of i,j, with the rate Tji or an unit mass chips off from the node i to j with the rate ω Tji. The hopping probability Tji is given as Tji= wji/Σ<l> wli, where the sum runs over the linked neighbors of the node i. On the WSFNs, we numerically show that a certain critical αc exists below which CA model undergoes the same type of the condensation transitions as those of CA model on regular lattices. However for α ≥ αc, the condensation always occurs for any density and ω. We analytically find αc = (γ-3)/2 on the WSFN with the degree exponent γ. To obtain αc, we analytically derive the scaling behavior of the stationary distribution P∞k of finding a walker at nodes with degree k, and the probability D(k) of finding two walkers simultaneously at the same node with degree k. We find P∞k kα+1-γ and D(k) k2(α+1)-γ respectively. With P∞k, we also show analytically and numerically that the average mass m(k) on a node with degree k scales as kα+1 without any jumps at the maximal degree of the network for any as in the SFNs with α=0.