Turbulence strength in ultimate Taylor-Couette turbulence

Abstract

We provide experimental measurements for the effective scaling of the Taylor-Reynolds number within the bulk Reλ,bulk, based on local flow quantities as a function of the driving strength (expressed as the Taylor number Ta), in the ultimate regime of Taylor-Couette flow. The data are obtained through flow velocity field measurements using Particle Image Velocimetry (PIV). We estimate the value of the local dissipation rate ε(r) using the scaling of the second order velocity structure functions in the longitudinal and transverse direction within the inertial range---without invoking Taylor's hypothesis. We find an effective scaling of εbulk /(3d-4) Ta1.40, (corresponding to Nuω,bulk Ta0.40 for the dimensionless local angular velocity transfer), which is nearly the same as for the global energy dissipation rate obtained from both torque measurements (Nuω Ta0.40) and Direct Numerical Simulations (Nuω Ta0.38). The resulting Kolmogorov length scale is then found to scale as ηbulk/d Ta-0.35 and the turbulence intensity as Iθ,bulk Ta-0.061. With both the local dissipation rate and the local fluctuations available we finally find that the Taylor-Reynolds number effectively scales as Reλ,bulk Ta0.18 in the present parameter regime of 4.0 × 108 < Ta < 9.0 × 1010.