Finite scale lyapunov analysis of temperature fluctuations in homogeneous isotropic turbulence

This study analyzes the temperature fluctuations in incompressible homogeneous isotropic turbulence through the finite scale Lyapunov analysis of the relative motion between two fluid particles. The analysis determines the temperature fluctuations through the Lyapunov theory of the local deformation, using the thermal energy equation. The study provides an explanation of the mechanism of temperature cascade, leads to the closure of the Corrsin equation, and describes the statistics of the longitudinal temperature derivative. The results here obtained show that, in the case of self-similarity of velocity and temperature correlations, the temperature spectrum exhibits the scaling laws $kappa^n$, with $n approx{-5/3}$, ${-1}$ and ${-17/3} div -11/3$ depending upon the flow regime, and in agreement with the theoretical arguments of Obukhov--Corrsin and Batchelor and with the numerical simulations and experiments known from the literature. The longitudinal temperature derivative PDF is found to be a non-gaussian distribution function with null skewness, whose intermittency rises with the Taylor scale P'eclet number. This study applies also to any passive scalar which exhibits diffusivity.