An analytical study of linear stability analysis on Soret driven ferrothermohaline convection in a Darcy porous medium with MFD viscosity and coriolis force
Dublin Core
Title
An analytical study of linear stability analysis on Soret driven ferrothermohaline convection in a Darcy porous medium with MFD viscosity and coriolis force
Subject
Coriolis force, Darcy Model, ferromagnetic fluid, MFD viscosity, perturbation technique, Soret Effect.
Description
The effect of magnetic field dependent (MFD) viscosity on the onset of Soret driven convection in a ferromagnetic fluid layer heated from below and salted from above saturating rotating porous medium in the presence of vertical magnetic field is investigated theoretically by using Darcy model. The resulting eigenvalue problem is solved using the regular perturbation technique. Both stationary and oscillatory instabilities have been obtained. It is found that increase in MFD viscosity and increase in magnetic Rayleigh number is to delay the onset of ferroconvection, while the nonlinearity of fluid magnetization has no influence on the stability of the system.
Journal of Naval Architecture and Marine Engineering Vol 19(2), December, 2022 p. 83-96
Journal of Naval Architecture and Marine Engineering Vol 19(2), December, 2022 p. 83-96
Creator
Murugan, D
Sekar, R
Source
Journal of Naval Architecture and Marine Engineering; Vol. 19 No. 2 (2022); 83-96
2070-8998
1813-8535
Publisher
Association of Naval Architects and Marine Engineers
Date
2023-01-03
Rights
Copyright (c) 2022 Journal of Naval Architecture and Marine Engineering
http://creativecommons.org/licenses/by-nc/4.0
Relation
Format
application/pdf
Language
eng
Type
info:eu-repo/semantics/article
info:eu-repo/semantics/publishedVersion
Identifier
Coverage
India
Citation
D Murugan and R Sekar, An analytical study of linear stability analysis on Soret driven ferrothermohaline convection in a Darcy porous medium with MFD viscosity and coriolis force, Association of Naval Architects and Marine Engineers, 2023, accessed November 6, 2024, https://igi.indrastra.com/items/show/3309