Laboratory Exploration of Heat Transfer Regimes in Rapidly Rotating Turbulent Convection

Abstract

We report heat transfer and temperature profile measurements in laboratory experiments of rapidly rotating convection in water under intense thermal forcing (Rayleigh number Ra as high as 1013) and unprecedentedly strong rotational influence (Ekman numbers E as low as 10-8). Measurements of the mid-height vertical temperature gradient connect quantitatively to predictions from numerical models of asymptotically rapidly rotating convection, separating various flow phenomenologies. Past the limit of validity of the asymptotically-reduced models, we find novel behaviors in a regime we refer to as rotationally-influenced turbulence, where rotation is important but not as dominant as in the known geostrophic turbulence regime. The temperature gradients collapse to a Rayleigh-number scaling as Ra-0.2 in this new regime. It is bounded from above by a critical convective Rossby number Ro*=0.06 independent of domain aspect ratio , clearly distinguishing it from well-studied rotation-affected convection.