Long-wave instability of stratified two-phase MHD flow
Arseniy Parfenov, Alexander Gelfgat, and Neima Brauner

TL;DR
This paper investigates how a transverse magnetic field affects the long-wave instability of stratified two-phase flows between plates, revealing complex stabilizing and destabilizing effects depending on boundary conditions and magnetic strength.
Contribution
It extends long-wave stability analysis to higher order terms and compares insulating versus conducting boundaries in MHD stratified flows, highlighting non-monotonic magnetic effects.
Findings
Magnetic field can both stabilize and destabilize the flow.
Disturbance profiles differ significantly between boundary conditions.
Flow destabilization can occur despite magnetic damping due to interface interactions.
Abstract
Instability of a stratified two-phase MHD parallel flow between two infinite plates is addressed. We examine the effect of the transverse magnetic field on the base flow and long wave instability of a two-layer system consisting of conductive liquid and non-conductive gas. Both perfectly insulating and perfectly conducting boundaries are considered. To capture the behavior at small but finite wavenumbers, the conventional first-order long-wave stability analysis is extended to higher order terms. Using mercury-air system as a representative test case, the results demonstrate distinct and non-similar base flow and disturbance profiles, as well as different stability maps for insulating versus conducting boundaries. The stability diagrams reveal a non-monotonic influence of the magnetic field on flow stability, showing that, in addition to its expected stabilizing effect, the field can…
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Taxonomy
TopicsFluid Dynamics and Thin Films · Fluid Dynamics and Heat Transfer · Heat Transfer and Boiling Studies
