Experimental Evidence for Longitudinal Scaling Exponent Saturation in Shear Turbulence

Abstract

The asymptotic behavior of velocity statistics in the tails of distributions and at high Reynolds numbers remains unresolved in turbulence. To investigate this behavior we measured the nth-order moments of the distributions of longitudinal velocity differences, Sn(r) [u(x+r)-u(x)]n rζn, in turbulent shear layers at Taylor-scale Reynolds numbers up to Reλ ≈ 1400. We used a nanoscale hot-wire probe with a sensing length, lw, that was about half the Kolmogorov scale, η. We obtained datasets that were up to 5× 107 integral timescales long, so that the statistics converged up to n=14. In the inertial range, the exponents, ζn, deviate from classical models and appear to saturate near ζn ≈ 2.2 0.1 for n 12. The saturation in the exponents is supported by a collapse of the tails of the velocity-difference distributions, and by plateaus in their compensated moments. These results constitute the first experimental evidence for scaling exponent saturation in longitudinal velocity increments, and is consistent with a dominance of localized vortex filaments in turbulence.