Abstract Changes in the Earth's rotation are deeply connected to fluid dynamical processes
in the outer core. This connection can be explored by studying the associated Earth …

Precession of planets or moons affects internal liquid layers by driving flows, instabilities and
possibly dynamos. The energy dissipated by these phenomena can influence orbital …

Fast changes of Earth's magnetic field could be explained by inviscid and diffusion‐less
quasi‐geostrophic (QG) Magneto‐Coriolis modes. We present a hybrid QG model with …

Precession of planets or moons affects internal liquid layers by driving flows, instabilities and
possibly dynamos. The energy dissipated by these phenomena can influence orbital …

Convection is thought to act as a turbulent viscosity in dam** tidal flows and in driving spin
and orbital evolution in close convective binary systems. This turbulent viscosity should be …

Motivated by modelling rotating turbulence in planetary fluid layers, we investigate
precession-driven flows in ellipsoids subject to stress-free boundary conditions (SF-BC). The …

Planets and satellites can undergo physical librations, which consist of forced periodic
variations in their rotation rate induced by gravitational interactions with nearby bodies. This …

In this paper, we present an experimental investigation of the turbulent saturation of the flow
driven by the parametric resonance of inertial waves in a rotating fluid. In our set-up, a half …

Turbulent convection is thought to act as an effective viscosity in dam** equilibrium tidal
flows, driving spin and orbital evolution in close convective binary systems. Compared to …

Tidal disruptions of stars on the equatorial plane orbiting Kerr black holes have been widely
studied. However, thus far, there have been fewer studies of stars in inclined precessing …