Suppressing instabilities in mixed baroclinic flow using an actuation based on receptivity

This paper presents a method to stabilise oscillations occurring in a mixed convective flow in a nearly hemispherical cavity, using an actuation modelled on the receptivity map of the unstable mode underpinning these oscillations. This configuration represents a simplified model inspired from the continuous casting of metallic alloys where hot liquid metal is poured at the top of a hot sump with cold walls pulled in a solid phase at the bottom. The model focuses on the underlying fundamental thermo-hydrodynamic processes without dealing with the complexity inherent to the real configuration (Flood & Davidson 1994). This flow exhibits three branches of instability (Kumar & Poth{\'e}rat 2020). By solving the adjoint eigenvalue problem for the convective flow equations, we find that the region of the highest receptivity for the unstable modes of each branch tends to concentrate near the inflow upper surface. Simulations of the linearised governing equations then reveal that a thermo-mechanical actuation modelled on the adjoint eigenmode suppresses the unstable mode over a finite time, after which it becomes destabilising. Based on this phenomenology, we apply the same actuation for the duration of the the stabilising phase only in the nonlinear evolution of the unstable mode. It turns out that the stabilisation persists, even when the unstable mode is left to evolve freely after the actuation period. Besides demonstrating the effectiveness of receptivity-informed actuation for the purpose of stabilising convective oscillations, these results potentially open the way to a simple strategy to control them during arbitrarily long periods of time.