Collapse of Coherent Large Scale Flow in Strongly Turbulent Liquid Metal Convection
Abstract
The large-scale flow structure and the turbulent transfer of heat and momentum are directly measured in highly turbulent liquid metal convection experiments for Rayleigh numbers varied between 4 × 105 and ≤ 5 × 109 and Prandtl numbers of 0.025~≤~Pr~≤ ~0.033. Our measurements are performed in two cylindrical samples of aspect ratios = diameter/height = 0.5 and 1 filled with the eutectic alloy GaInSn. The reconstruction of the three-dimensional flow pattern by 17 ultrasound Doppler velocimetry sensors detecting the velocity profiles along their beamlines in different planes reveals a clear breakdown of coherence of the large-scale circulation for = 0.5. As a consequence, the scaling laws for heat and momentum transfer inherit a dependence on the aspect ratio. We show that this breakdown of coherence is accompanied with a reduction of the Reynolds number Re. The scaling exponent β of the power law Nu Raβ crosses eventually over from β=0.221 to 0.124 when the liquid metal flow at =0.5 reaches Ra 2× 108 and the coherent large-scale flow is completely collapsed.
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