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Fluid Dynamics Experiments for Planetary Interiors

Michaël Le Bars, Ankit Barik, Fabian Burmann, Daniel P. Lathrop, Jérõme Noir, Nathanaël Schaeffer, S. A. Triana

2022Repository for Publications and Research Data (ETH Zurich)27 citationsDOIOpen Access PDF

Abstract

Understanding fluid flows in planetary cores and subsurface oceans, as well as their signatures in available observational data (gravity, magnetism, rotation, etc.), is a tremendous interdisciplinary challenge. In particular, it requires understanding the fundamental fluid dynamics involving turbulence and rotation at typical scales well beyond our day-to-day experience. To do so, laboratory experiments are fully complementary to numerical simulations, especially in systematically exploring extreme flow regimes for long duration. In this review article, we present some illustrative examples where experimental approaches, complemented by theoretical and numerical studies, have been key for a better understanding of planetary interior flows driven by some type of mechanical forcing. We successively address the dynamics of flows driven by precession, by libration, by differential rotation, and by boundary topography.

Topics & Concepts

Rotation (mathematics)GeophysicsForcing (mathematics)PrecessionGeophysical fluid dynamicsTurbulenceMechanicsGeologyFluid dynamicsPhysicsLibration (molecule)Flow (mathematics)Classical mechanicsGeometryAstronomyAtmospheric sciencesMathematicsPoint (geometry)Geomagnetism and Paleomagnetism StudiesAstro and Planetary SciencePlanetary Science and Exploration
Fluid Dynamics Experiments for Planetary Interiors | Litcius