Turbulence is an Ineffective Mixer when Schmidt Numbers Are Large

We solve the advection-diffusion equation for a stochastically stationary passive scalar theta, in conjunction with forced 3D Navier-Stokes equations, using direct numerical simulations in periodic domains of various sizes, the largest being 8192(3). The Taylor-scale Reynolds number varies in the range 140-650 and the Schmidt number Sc nu/D in the range 1-512, where nu is the kinematic viscosity of the fluid and D is the molecular diffusivity of theta. Our results show that turbulence becomes an ineffective mixer when Sc is large. First, the mean scalar dissipation rate <chi > = 2D <vertical bar del theta vertical bar(2)>, when suitably nondimensionalized, decreases as 1/log Sc. Second, 1D cuts through the scalar field indicate increasing density of sharp fronts on larger scales, oscillating with large excursions leading to reduced mixing, and additionally suggesting weakening of scalar variance flux across the scales. The scaling exponents of the scalar structure functions in the inertial-convective range appear to saturate with respect to the moment order and the saturation exponent approaches unity as Sc increases, qualitatively consistent with 1D cuts of the scalar.