Universal Statistical Properties of Inertial-particle Trajectories in Three-dimensional, Homogeneous, Isotropic, Fluid Turbulence

Abstract

We uncover universal statistical properties of the trajectories of heavy inertial particles in three-dimensional, statistically steady, homogeneous, and isotropic turbulent flows by extensive direct numerical simulations. We show that the probability distribution functions (PDFs) P(φ), of the angle φ between the Eulerian velocity u and the particle velocity v, at this point and time, shows a power-law region in which P(φ) φ-γ, with a new universal exponent γ 4. Furthermore, the PDFs of the trajectory curvature and modulus θ of the torsion have power-law tails that scale, respectively, as P() -h, as ∞, and P(θ) θ-hθ, as θ ∞, with exponents h 2.5 and hθ 3 that are universal to the extent that they do not depend on the Stokes number St (given our error bars). We also show that γ, h and hθ can be obtained by using simple stochastic models. We characterize the complexity of heavy-particle trajectories by the number N I(t, St) of points (up until time t) at which changes sign. We show that n I( St) t∞ N I(t, St)t St-, with 0.4 a universal exponent.