Nonequilibrium phase transitions and finite size scaling in weighted scale-free networks
arXiv:cond-mat/0504666 · doi:10.1103/PhysRevE.73.036116
Abstract
We consider nonequilibrium phase transitions in weighted scale-free networks, in which highly connected nodes, which are created earlier in time are partially immunized. For epidemic spreading we solve the dynamical mean-field equations and discuss finite-size scaling theory. The theoretical predictions are confronted with the results of large scale Monte Carlo simulations on the weighted Barabási-Albert network. Local scaling exponents are found different at a typical site and at a node with very large connectivity.
6 pages, 5 figures