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Vibration-induced boundary-layer destabilization achieves massive heat-transport enhancement

Bo-Fu Wang, Quan Zhou, Chao Sun

2020Science Advances133 citationsDOIOpen Access PDF

Abstract

Thermal turbulence is well known as a potent means to convey heat across space by a moving fluid. The existence of the boundary layers near the plates, however, bottlenecks its heat-exchange capability. Here, we conceptualize a mechanism of thermal vibrational turbulence that breaks through the boundary-layer limitation and achieves massive heat-transport enhancement. When horizontal vibration is applied to the convection cell, a strong shear is induced to the body of fluid near the conducting plates, which destabilizes thermal boundary layers, vigorously triggers the eruptions of thermal plumes, and leads to a heat-transport enhancement by up to 600%. We further reveal that such a vibration-induced shear can very efficiently disrupt the boundary layers. The present findings open a new avenue for research into heat transport and will also bring profound changes in many industrial applications where thermal flux through a fluid is involved and the mechanical vibration is usually inevitable.

Topics & Concepts

Boundary layerVibrationLayer (electronics)Boundary (topology)Materials scienceMechanicsBiophysicsAcousticsComposite materialPhysicsBiologyMathematicsMathematical analysisFluid Dynamics and Turbulent FlowsNanofluid Flow and Heat TransferHeat Transfer Mechanisms
Vibration-induced boundary-layer destabilization achieves massive heat-transport enhancement | Litcius