The engineering and science behind a laboratory model of the Earth's outer core: 12.5 tons of rapidly rotating liquid sodium

Laboratory turbulence experiments are a natural place for examining planetary fluid flows. Rotation, shear, zonal flows, and the associated torques/angular momentum fluxes are all easily instantiated in the lab. In addition, by using a conducting fluid one can study the conditions of planetary cores and magnetic field / fluid interactions.  Using a series of experiments, of increasing size and increasing power input (now a three-meter diameter system), we have examined liquid sodium spherical Couette flows to better understand planetary cores. The engineering and safety planning challenges in building an experiment with 12.5 tons of metallic sodium rotating at 4 Hz were an interesting part of the project. We have uncovered precessional flows, inertial waves, turbulent bi-stability, many turbulent states, magnetic field gain by the Omega effect, all while being sub-dynamo.  In addition, we are exploring how machine-learning tools can be used to do short-term prediction of the time evolution of our turbulent laboratory magnetic field variation. We have modified the experiment this year to increase the helicity in the system by putting baffles on the inner sphere as motivated by Finke and Tilgner’s computational dynamo studies, and are preparing new experiments for this Fall.