A comparative experimental and numerical study of rotating Rayleigh-B\'{e}nard convection in a cylindrical cell

Rotating Rayleigh-B\'{e}nard convection (RBC) is the buoyancy-driven flow resulting from temperature gradients parallel to the gravity in the presence of rotation. In this work we comparatively present the results from an experimental and numerical investigation of RBC in a cylindrical cell with aspect ratio of 1/2 in non-rotating conditions and at different Rossby numbers. On the experimental side, time-resolved tomo-PTV is used to perform whole-field velocity measurements in a cell immersed in a water tank with constant controlled bulk temperature. This setup is accurately modeled in the direct numerical simulations by including the presence of the sidewall in the computational domain and solving the temperature field in both the fluid and solid regions. Excellent agreement between experiments and DNS is found for the non-rotating convection, whereas some discrepancies are observed when rotation is added. The latter might be related to the specific motions in the water tank at the outside of the experimental cell.