Energy transfer and dissipation in forced isotropic turbulence

Abstract

A model for the Reynolds number dependence of the dimensionless dissipation rate C was derived from the dimensionless K\'arm\'an-Howarth equation, resulting in C=C, ∞ + C/RL + O(1/RL2), where RL is the integral scale Reynolds number. The coefficients C and C,∞ arise from asymptotic expansions of the dimensionless second- and third-order structure functions. This theoretical work was supplemented by direct numerical simulations (DNSs) of forced isotropic turbulence for integral scale Reynolds numbers up to RL=5875 (Rλ=435), which were used to establish that the decay of dimensionless dissipation with increasing Reynolds number took the form of a power law RLn with exponent value n = -1.000 0.009, and that this decay of C was actually due to the increase in the Taylor surrogate U3/L. The model equation was fitted to data from the DNS which resulted in the value C=18.9 1.3 and in an asymptotic value for C in the infinite Reynolds number limit of C,∞ = 0.468 0.006.