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Collapse of Coherent Large Scale Flow in Strongly Turbulent Liquid Metal Convection

Felix Schindler, Sven Eckert, Till Zürner, Jörg Schumacher, Tobias Vogt

2022Physical Review Letters32 citationsDOIOpen Access PDF

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 4×10^{5} and ≤5×10^{9} and Prandtl numbers of 0.025≤Pr≤0.033. Our measurements are performed in two cylindrical samples of aspect ratios Γ=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 beam lines in different planes reveals a clear breakdown of coherence of the large-scale circulation for Γ=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∝Ra^{β} crosses eventually over from β=0.221 to 0.124 when the liquid metal flow at Γ=0.5 reaches Ra≳2×10^{8} and the coherent large-scale flow is completely collapsed.

Topics & Concepts

TurbulencePrandtl numberPhysicsMechanicsReynolds numberScalingHeat transferConvectionFlow (mathematics)Coherence (philosophical gambling strategy)Momentum (technical analysis)Momentum transferTurbulent Prandtl numberRayleigh numberMaterials scienceConvective heat transferVelocimetryJet (fluid)VortexFlow visualizationPower lawOpticsRayleigh scatteringPipe flowMomentum diffusionRayleigh–Bénard convectionMBBAClassical mechanicsOpen-channel flowHeat fluxReynolds stressFlow separationFlow measurementSolidification and crystal growth phenomenaFluid Dynamics and Turbulent FlowsAdvanced Thermodynamic Systems and Engines