Dynamical transition of hydromagnetic convection in a rotating fluid layer

TL;DR

This paper investigates the stability and dynamic transition of a rotating, magnetized fluid layer using theoretical and numerical methods, revealing conditions for different transition types and flow patterns.

Contribution

It introduces a hybrid analytical and numerical approach to analyze stability and transitions in magnetohydrodynamic convection with rotation.

Findings

Both continuous and jump transitions can occur depending on parameters.

Transition numbers determine the type of dynamic transition.

Flow patterns vary with different transition scenarios.

Abstract

In this article, we aim to study the stability and dynamic transition of an electrically conducting fluid in the presence of an external uniform horizontal magnetic field and rotation based on a Boussinesq approximation model. By analyzing the spectrum of the linear part of the model and verifying the validity of the principle of exchange of stability, we take a hybrid approach combining theoretical analysis with numerical computation to study the transition from a simple real eigenvalue, a pair of complex conjugate eigenvalues and a real eigenvalue of multiplicity two, respectively. The center manifold reduction theory is applied to reduce the infinite dimensional system to the corresponding finite dimensional one together with one or several non-dimensional transition numbers that determine the dynamic transition types. Careful numerical computations are performed to determine these transition numbers as well as related temporal and flow patterns etc. Our results indicate that both continuous and jump transitions can occur at certain parameter region.