Nusselt number scaling in horizontal convection

Abstract

We report a numerical study of horizontal convection (HC) at Prandtl number Pr = 1, with both no-slip and free-slip boundary conditions. We obtain 2D and 3D solutions and determine the relation between the Rayleigh number Ra and the Nusselt number Nu. In 2D we vary Ra between 0 and 1014. In the range 106 Ra 1010 the Nu-Ra relation is Nu Ra1/5. With Ra greater than about 1011 we find a 2D regime with Nu Ra1/4 over three decades, up to the highest 2D Ra. In 3D, with maximum Ra = 1011.5, we find only Nu Ra1/5. These results apply to both free slip and no slip boundary conditions. The Nu Ra1/4 regime has a double boundary layer (BL): there is a thin BL with thickness Ra-1/4 nested inside a thicker BL with thickness Ra-1/5. The Ra-1/4 BL thickness, which determines Nu, coincides with the Kolmogorov and Batchelor scales of HC. Numerical and theoretical results indicate that 3D HC is qualitatively and quantitatively similar to 2D HC. At the same Ra, the 3D Nu exceeds the 2D Nu by less than 20%, i.e., there is very little 3D enhancement of heat transport. Boundary conditions are more important than dimensionality: the 2D free-slip solutions have larger Nu than 3D no-slip solutions. Using the mechanical energy power integral of HC we show that the mean square vorticity of 3D HC is nearly equal to that of 2D HC at the same Ra. Thus vorticity amplification by strain-mediated vortex stretching does not operate in 3D HC.