Tailoring boundary geometry to optimize heat transport in turbulent convection

Abstract

By tailoring the geometry of the upper boundary in turbulent Rayleigh-B\'enard convection we manipulate the boundary layer -- interior flow interaction, and examine the heat transport using the Lattice Boltzmann method. For fixed amplitude and varying boundary wavelength λ, we find that the exponent β in the Nusselt-Rayleigh scaling relation, Nu-1 Raβ, is maximized at λ λmax ≈ (2 π)-1, but decays to the planar value in both the large (λ λmax) and small (λ λmax) wavelength limits. The changes in the exponent originate in the nature of the coupling between the boundary layer and the interior flow. We present a simple scaling argument embodying this coupling, which describes the maximal convective heat flux.