A geophysical-scale model of vertical natural convection boundary layers

• Published in: Journal of fluid mechanics Vol. 609; pp. 111 - 137
• Main Authors: WELLS, ANDREW J., WORSTER, M. GRAE
• Format: Journal Article
• Language: English
• Published: Cambridge, UK Cambridge University Press 25.08.2008
• Subjects: Boundary layer; Earth, ocean, space; Exact sciences and technology; External geophysics; Fluid mechanics; Geophysics. Techniques, methods, instrumentation and models; Turbulence; Turbulence models; Scaling law; plumes; Vertical wall; boundary layer; turbulent flow; Natural convection; digital simulation; Geophysical fluid dynamics; Modeling; heat transfer
• ISSN: 0022-1120; 1469-7645
• DOI: 10.1017/S0022112008002346

A model is developed for turbulent natural convection in boundary layers formed next to isothermal vertical surfaces. A scaling analysis shows that the flow can be described by plume equations for an outer turbulent region coupled to a resolved near-wall laminar flow. On the laboratory scale, the inner layer is dominated by its own buoyancy and the Nusselt number scales as the one-third power of the Rayleigh number (Nu ∝ ${\it Ra}_z^{1/3}$). This gives a constant heat flux, consistent with previous experimental and theoretical studies. On larger geophysical scales the buoyancy is strongest in the outer layer and the laminar layer is driven by the shear imposed on it. The predicted heat transfer correlation then has the Nusselt number proportional to the one-half power of Rayleigh number (Nu ∝ ${\it Ra}_z^{1/2}$) so that a larger heat flux is predicted than might be expected from an extrapolation of laboratory-scale results. The criteria for transitions between flow regimes are consistent with a hierarchy of instabilities of the near-wall laminar flow, with a buoyancy-driven instability operating on the laboratory scale and a shear-driven instability operating on geophysical scales.