Thermal convection in a rotating viscoelastic fluid saturated porous layer

Linear and nonlinear stability of a rotating viscoelastic fluid saturated porous layer heated from below is studied analytically. The modified Darcy–Oldroyd model that includes the time derivative and Coriolis terms is employed as a momentum equation. The onset criterion for both stationary and osci...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2010-12, Vol.53 (25), p.5747-5756
Main Authors: Malashetty, M.S., Swamy, M.S., Sidram, W.
Format: Article
Language:English
Subjects:
Buoyancy-driven instability
Convection
Convection modes
Exact sciences and technology
Flows through porous media
Fluid dynamics
Fundamental areas of phenomenology (including applications)
Hydrodynamic stability
Mathematical analysis
Mathematical models
Non-newtonian fluid flows
Nonhomogeneous flows
Nonlinearity
Oscillatory stationary convection
Physics
Porous medium
Rotation
Stability
Stress relaxation
Thermal convection
Viscoelastic fluid
Viscoelastic fluids
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Summary:Linear and nonlinear stability of a rotating viscoelastic fluid saturated porous layer heated from below is studied analytically. The modified Darcy–Oldroyd model that includes the time derivative and Coriolis terms is employed as a momentum equation. The onset criterion for both stationary and oscillatory convection is derived as a function of Taylor number, Darcy–Prandtl number and viscoelastic parameters. There is a competition between the processes of rotation, viscous relaxation and thermal diffusion that causes the convection to set in through oscillatory mode rather than stationary. The rotation inhibits the onset of convection in both stationary and oscillatory modes. The stress relaxation parameter destabilizes the system towards the oscillatory mode, while the strain retardation parameter enhances the stability. The effect of Darcy–Prandtl number on the stability of the system is also investigated. The nonlinear theory is based on the truncated representation of Fourier series method. The effect of rotation, stress relaxation and strain-retardation time and also the Darcy–Prandtl number on the transient heat transfer is presented graphically.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2010.08.008