Statistics of the relative velocity of particles in turbulent flows : monodisperse particles

Abstract

We use direct numerical simulations to calculate the joint probability density function of the relative distance R and relative radial velocity component VR for a pair of heavy inertial particles suspended in homogeneous and isotropic turbulent flows. At small scales the distribution is scale invariant, with a scaling exponent that is related to the particle-particle correlation dimension in phase space, D2. It was argued [1, 2] that the scale invariant part of the distribution has two asymptotic regimes: (1) |VR| R where the distribution depends solely on R; and (2) |VR| R where the distribution is a function of |VR| alone. The probability distributions in these two regimes are matched along a straight line |VR| = z R. Our simulations confirm that this is indeed correct. We further obtain D2 and z as a function of the Stokes number, St. The former depends non-monotonically on St with a minimum at about St ≈ 0.7 and the latter has only a weak dependence on St.