Rayleigh–Bénard stability and the validity of quasi-Boussinesq or quasi-anelastic liquid approximations

The linear stability threshold of the Rayleigh–Bénard configuration is analysed with compressible effects taken into account. It is assumed that the fluid under investigation obeys a Newtonian rheology and Fourier’s law of thermal transport with constant, uniform (dynamic) viscosity and thermal cond...

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Bibliographic Details
Published in:Journal of fluid mechanics 2017-04, Vol.817, p.264-305
Main Authors: Alboussière, Thierry, Ricard, Yanick
Format: Article
Language:English
Subjects:
Anelasticity
Approximation
Boundaries
Boundary conditions
Boussinesq approximation
Chebyshev approximation
Coefficients
Compressibility
Convection
Entropy
Equations of state
Fluid mechanics
Fluids
Formulas (mathematics)
Fourier law
Geophysics
Gravitation
Gravity
Gravity field
Ideal gas
Mathematical models
Mechanical properties
Parameters
Perturbations
Physics
Rayleigh number
Rheological properties
Rheology
Stability
Stability analysis
Temperature
Temperature differences
Temperature effects
Temperature gradients
Thermal conductivity
Thermal expansion
Viscosity
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Summary:The linear stability threshold of the Rayleigh–Bénard configuration is analysed with compressible effects taken into account. It is assumed that the fluid under investigation obeys a Newtonian rheology and Fourier’s law of thermal transport with constant, uniform (dynamic) viscosity and thermal conductivity in a uniform gravity field. Top and bottom boundaries are maintained at different constant temperatures and we consider here mechanical boundary conditions of zero tangential stress and impermeable walls. Under these conditions, and with the Boussinesq approximation, Rayleigh (Phil. Mag., vol. 32 (192), 1916, pp. 529–546) first obtained analytically the critical value $27\unicode[STIX]{x03C0}^{4}/4$ for a dimensionless parameter, now known as the Rayleigh number, at the onset of convection. This paper describes the changes of the critical Rayleigh number due to the compressibility of the fluid, measured by the dimensionless dissipation parameter ${\mathcal{D}}$ and due to a finite temperature difference between the hot and cold boundaries, measured by a dimensionless temperature gradient $a$ . Different equations of state are examined: ideal gas equation, Murnaghan’s model (often used to describe the interiors of solid but convective planets) and a generic equation of state with adjustable parameters, which can represent any possible equation of state. In the perspective to assess approximations often made in convective models, we also consider two variations of this stability analysis. In a so-called quasi-Boussinesq model, we consider that density perturbations are solely due to temperature perturbations. In a so-called quasi-anelastic liquid approximation model, we consider that entropy perturbations are solely due to temperature perturbations. In addition to the numerical Chebyshev-based stability analysis, an analytical approximation is obtained when temperature fluctuations are written as a combination of only two modes, one being the original symmetrical (between top and bottom) mode introduced by Rayleigh, the other one being antisymmetrical. The analytical solution allows us to show that the antisymmetrical part of the critical eigenmode increases linearly with the parameters $a$ and ${\mathcal{D}}$ , while the superadiabatic critical Rayleigh number departs quadratically in $a$ and ${\mathcal{D}}$ from $27\unicode[STIX]{x03C0}^{4}/4$ . For any arbitrary equation of state, the coefficients of the quadratic departure are determined analytically
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2017.108