Roughness as a Route to the Ultimate Regime of Thermal Convection

Abstract

We use highly resolved numerical simulations to study turbulent Rayleigh-B\'enard convection in a cell with sinusoidally rough upper and lower surfaces in two dimensions for Pr = 1 and Ra = [4 × 106, 3 × 109]. By varying the wavelength λ at a fixed amplitude, we find an optimal wavelength λopt for which the Nusselt-Rayleigh scaling relation is (Nu-1 Ra0.483) maximizing the heat flux. This is consistent with the upper bound of Goluskin and Doering Goluskin:2016 who prove that Nu can grow no faster than O (Ra1/2) as Ra → ∞, and thus the concept that roughness facilitates the attainment of the so-called ultimate regime. Our data nearly achieve the largest growth rate permitted by the bound. When λ λopt and λ λopt, the planar case is recovered, demonstrating how controlling the wall geometry manipulates the interaction between the boundary layers and the core flow. Finally, for each Ra we choose the maximum Nu among all λ, and thus optimizing over all λ, to find Nuopt - 1 = 0.01 × Ra0.444.