Scale-invariance and characteristic length scale for the large-scale vortices in geostrophic convective turbulence with friction

Abstract

In geostrophic convective turbulence, large-scale vortices (LSVs) emerge through upscale energy transfer and are commonly regulated by large-scale friction. Yet the role of friction in setting the LSV size remains poorly understood. Here we perform direct numerical simulations of rotating Rayleigh-Benard convection with a linear friction term αu. Contrary to the classical prediction Lαα-3/2 obtained from the Kraichnan-Leith-Batchelor (KLB) theory, we find that the LSV radius follows RLSVα-1/2. This discrepancy originates from the energy spectrum of the barotropic (2D) manifold, which exhibits E2D(k) k-3 over the range of upscale energy transfer, rather than the canonical k-5/3 scaling. To explain this behavior, we analyze the energy pathways of the barotropic manifold and show that the inverse transfer is strongly nonlocal, coupling a broad range of intermediate scales directly to the cutoff scale. We propose that this coupling leads to a balance between the local and large-scale shear strain rates, resulting in a scale-invariant coarse-grained vorticity. The resulting prediction E2D(k) k-3 is supported by circulation statistics exhibiting |Γ(r)| r2. The observed k-3 spectrum naturally yields the scaling RLSVα-1/2. These results provide a physical interpretation for the widely observed k-3 spectrum in condensation-dominated turbulence and suggest that LSV-size estimates based on the classical k-5/3 spectrum may be significantly biased in geophysical and astrophysical flows.