On Turbulent Particle Pair Diffusion

Abstract

Richardson's theory of turbulent particle pair diffusion [Richardson, L. F. Proc. Roy. Soc. Lond. A 100, 709--737, 1926], based upon observational data, is equivalent to a locality hypothesis in which the turbulent pair diffusivity (K) scales with the pair separation (σl) with a 4/3-power law, K σl4/3. Here, a reappraisal of the 1926 dataset reveals that one of the data-points is from a molecular diffusion context; the remaining data from geophysical turbulence display an unequivocal non-local scaling, K σl1.564. Consequently, the foundations of pair diffusion theory have been re-examined, leading to a new theory based upon the principle that both local and non-local diffusional processes govern pair diffusion in homogeneous turbulence. Through a novel mathematical approach the theory is developed in the context of generalised power law energy spectra, E(k) k-p for 1<p 3, over extended inertial subranges. The theory predicts the scaling, K(p) σlγp, with γp intermediate between the purely local and the purely non-local scalings, i.e. (1+p)/2<γp 2. A Lagrangian diffusion model, Kinematic Simulations [Kraichnan, R. H., Phys. Fluids 13, 22-31, 1970; Fung et al., J. Fluid Mech. 236, 281-318, 1992], is used to examine the predictions of the new theory all of which are confirmed. The simulations produce the scalings, K σl1.545 to σl1.570, in the accepted range of intermittent turbulence spectra, E(k) k-1.72 to k-1.74, in close agreement with the revised 1926 dataset.