Utilizing indicator functions with computational data to confirm nature of overlap in normal turbulent stresses: logarithmic or quarter-power
Abstract
Indicator functions of the streamwise normal-stress profiles (NSP), based on careful differentiation of some of the best direct numerical simulations (DNS) data from channel and pipe flows, over the range 550<Reτ<16,000, are examined to establish the existence and range in wall distances of either a logarithmic-trend segment or a 1/4-power region. For the nine out of fifteen cases of DNS data we examined where Reτ<2,000, the NSP did not contain either of the proposed trends. As Reτ exceeds around 2,000 a 1/4-power, reflecting the ``bounded-dissipation'' predictions of Chen \& Sreenivasan and data analysis of Monkewitz , develops near y+=1,000 and expands with Reynolds numbers extending to 1,000<y+<10,000 for Reτ around 15,000. This range of 1/4-power NSP corresponds to a range of outer-scaled Y between around 0.3 and 0.7. The computational database examined did not include the zero-pressure-gradient boundary layer experiments at higher Reynolds numbers where the logarithmic trend in the NSP has been previously reported around y+ of 1,000 by Marusic et al. according to a ``wall-scaled eddy model''.
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