Two-Particle Dispersion in Model Velocity Fields

We consider two-particle dispersion in a velocity field, where the relative two-point velocity scales according to $v^{2}(r)\propto r^{\alpha}$ and the corresponding correlation time scales as $\tau (r)\propto r^{\beta}$, and fix $\alpha =2/3$, as typical for turbulent flows. We show that two generic types of dispersion behavior arize: For $\alpha /2+\beta < 1$ the correlations in relative velocities decouple and the diffusion approximation holds. In the opposite case, $\alpha /2+\beta >1$, the relative motion is strongly correlated. The case of Kolmogorov flows corresponds to a marginal, nongeneric situation.Comment: 4 pages, 4 figures, Late

Canonical fitness model for simple scale-free graphs

We consider a fitness model assumed to generate simple graphs with power-law heavy-tailed degree sequence: P(k) \propto k^{-1-\alpha} with 0 < \alpha < 1, in which the corresponding distributions do not posses a mean. We discuss the situations in which the model is used to produce a multigraph and examine what happens if the multiple edges are merged to a single one and thus a simple graph is built. We give the relation between the (normalized) fitness parameter r and the expected degree \nu of a node and show analytically that it possesses non-trivial intermediate and final asymptotic behaviors. We show that the model produces P(k) \propto k^{-2} for large values of k independent of \alpha. Our analytical findings are confirmed by numerical simulations.Comment: 6 pages, 2 figures; published in Phys. Rev. E. To improve readability, formulas and text were added between Eq. (1) and (2