Bounds on buoyancy driven flows with Navier-slip conditions on rough boundaries

Abstract

We consider two-dimensional Rayleigh-B\'enard convection with Navier-slip and fixed temperature boundary conditions at the two horizontal rough walls described by the height function h. We prove rigorous upper bounds on the Nusselt number Nu which capture the dependence on the curvature of the boundary and the (non-constant) friction coefficient α explicitly. If h∈ W2,∞ and satisfies a smallness condition with respect to α, we find Nu Ra12+\|\|∞\,, where Ra is the Rayleigh number, which agrees with the predicted Spiegel-Kraichnan scaling when =0. This bound is obtained via local regularity estimates in a small strip at the boundary. When h∈ W3,∞, the functions and α are sufficiently small in L∞ and the Prandtl number is sufficiently large, we prove upper bounds using the background field method, which interpolate between Ra12 and Ra512 with non-trivial dependence on α and . These bounds agree with the result in Drivas et al (2022 Phil. Trans. R. Soc. A 380 20210025) for flat boundaries and constant friction coefficient. Furthermore, in the regime ≥ Ra 57, we improve the Ra 12-upper bound, showing Nuα,Ra37\,, where α, hides an additional dependency of the implicit constant on α and .

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