Condensation phase transitions of symmetric conserved-mass aggregation model on complex networks
Abstract
We investigate condensation phase transitions of symmetric conserved-mass aggregation (SCA) model on random networks (RNs) and scale-free networks (SFNs) with degree distribution P(k) k-γ. In SCA model, masses diffuse with unite rate, and unit mass chips off from mass with rate ω. The dynamics conserves total mass density . In the steady state, on RNs and SFNs with γ>3 for ω ≠ ∞, we numerically show that SCA model undergoes the same type condensation transitions as those on regular lattices. However the critical line c (ω) depends on network structures. On SFNs with γ ≤ 3, the fluid phase of exponential mass distribution completely disappears and no phase transitions occurs. Instead, the condensation with exponentially decaying background mass distribution always takes place for any non-zero density. For the existence of the condensed phase for γ ≤ 3 at the zero density limit, we investigate one lamb-lion problem on RNs and SFNs. We numerically show that a lamb survives indefinitely with finite survival probability on RNs and SFNs with γ >3, and dies out exponentially on SFNs with γ ≤ 3. The finite life time of a lamb on SFNs with γ ≤ 3 ensures the existence of the condensation at the zero density limit on SFNs with γ ≤ 3 at which direct numerical simulations are practically impossible. At ω = ∞, we numerically confirm that complete condensation takes place for any > 0 on RNs. Together with the recent study on SFNs, the complete condensation always occurs on both RNs and SFNs in zero range process with constant hopping rate.
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