Heat transport scaling and transition in geostrophic rotating convection with varying aspect ratio

Abstract

We present high-precision experimental and numerical studies of the Nusselt number Nu as functions of the Rayleigh number Ra in geostrophic rotating convection with domain aspect ratio varying from 0.4 to 3.8 and the Ekman number Ek from 2.0×10-7 to 2.7×10-5. The heat-transport data Nu(Ra) reveal a gradual transition from buoyancy-dominated to geostrophic convection at large Ek, whereas the transition becomes sharp with decreasing Ek. We determine the power-law scaling of NuRaγ, and show that the boundary flows give rise to pronounced enhancement of Nu in a broad range of the geostrophic regime, leading to reduction of the scaling exponent γ in small cells. The present work provides new insight into the heat-transport scaling in geostrophic convection and may explain the discrepancies observed in previous studies.