Non-Oberbeck-Boussinesq Effects in Gaseous Rayleigh-Bénard Convection

Ahlers, Guenter; Araujo, Francisco Fontenele; Fünfschilling, Denis; Großmann, S.; Lohse, Detlef

doi:10.1103/physrevlett.98.054501

Cited by 67 publications

(82 citation statements)

References 20 publications

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“…While in [171,172] the deviation of the centre temperature from the algebraic mean, T ref = (T bottom + T top )/2, is observed, Burnishev et al [61] report a high-Rayleigh-number NOB convection with symmetric temperature profiles and a scaling Nu ∼ Ra β which is comparable to the experiments in the OB limit at same Ra (see sect. 6).…”

Section: Non-oberbeck-boussinesq Effectssupporting

confidence: 51%

“…The anelastic approximation (5) is a first weak compressibility effect which is for example incorporated in atmospheric convection that exceeds layers of height H ≈ 2 km. Stronger compressibility effects and thus large variations of the fluid properties can arise when the working fluids are operated in the vicinity of their critical points as done in helium [171], in ethane [172], or in SF 6 [61].…”

Section: Non-oberbeck-boussinesq Effectsmentioning

confidence: 99%

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New perspectives in turbulent Rayleigh-Bénard convection

2012

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Abstract. Recent experimental, numerical and theoretical advances in turbulent Rayleigh-Bénard convection are presented. Particular emphasis is given to the physics and structure of the thermal and velocity boundary layers which play a key role for the better understanding of the turbulent transport of heat and momentum in convection at high and very high Rayleigh numbers. We also discuss important extensions of Rayleigh-Bénard convection such as non-Oberbeck-Boussinesq effects and convection with phase changes.

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Section: Non-oberbeck-boussinesq Effectssupporting

confidence: 51%

Section: Non-oberbeck-boussinesq Effectsmentioning

confidence: 99%

New perspectives in turbulent Rayleigh-Bénard convection

2012

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“…As the GL theory is based on the assumption that the BL thickness scales inversely proportional to the square root of the Reynolds number according to Prandtl's 1904 theory, the validity of Prandtl-Blasius BL flow needs to be tested also locally. Note that comparison of the mean bulk temperature calculated using the Prandtl-Blasius theory with that measured in both liquid and gaseous nonOberbeck-Boussinesq RB convection shows very good agreement [16][17][18] . In addition, the kinematic BL thickness evaluated by solving the laminar Prandtl-Blasius BL equations was found to agree well with that obtained in the direct numerical simulation (DNS) 19 .…”

Section: Introductionmentioning

confidence: 83%

Horizontal structures of velocity and temperature boundary layers in two-dimensional numerical turbulent Rayleigh-Bénard convection

Zhou¹,

Sugiyama²,

Stevens³

et al. 2011

Physics of Fluids

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We investigate the structures of the near-plate velocity and temperature profiles at different horizontal positions along the conducting bottom (and top) plate of a Rayleigh-Bénard convection cell, using two-dimensional (2D) numerical data obtained at the Rayleigh number Ra= 10 8 and the Prandtl number Pr= 4.4 of an Oberbeck-Boussinesq flow with constant material parameters. The results show that most of the time, and for both velocity and temperature, the instantaneous profiles scaled by the dynamical frame method [Q. Zhou and K.-Q. Xia, Phys. Rev. Lett. 104, 104301 (2010)] agree well with the classical Prandtl-Blasius laminar boundary layer (BL) profiles. Therefore, when averaging in the dynamical reference frames, which fluctuate with the respective instantaneous kinematic and thermal BL thicknesses, the obtained mean velocity and temperature profiles are also of Prandtl-Blasius type for nearly all horizontal positions. We further show that in certain situations the traditional definitions based on the time-averaged profiles can lead to unphysical BL thicknesses, while the dynamical method also in such cases can provide a well-defined BL thickness for both the kinematic and the thermal BLs.

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“…On the other hand, the limit Z → 0 corresponds to the so-called Oberbeck-Boussinesq approximation, where both stratification and compressibility are vanishingly small. The latter is, by far, the most studied convection configuration, even though some important applications for astrophysics [45,46] and recently also for laboratory set-up [47][48][49] cannot neglect compressible modes. It is possible to show [35] that in the Boussinesq approximation, the dependency from the polytropic index disappear (as it must obviously do) while it remains a possible effect induced by the adiabatic gradient (usually small on laboratory experiments, but not necessarily on atmospheric scales).…”

Section: Transition To Convection In Rayleigh-bénard Compressiblmentioning

confidence: 99%

Lattice Boltzmann methods for thermal flows: Continuum limit and applications to compressible Rayleigh–Taylor systems

Scagliarini¹,

Biferale²,

Sbragaglia

et al. 2010

Physics of Fluids

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We compute the continuum thermo-hydrodynamical limit of a new formulation of lattice kinetic equations for thermal compressible flows, recently proposed in [Sbragaglia et al., J. Fluid Mech. 628 299 (2009)]. We show that the hydrodynamical manifold is given by the correct compressible FourierNavier-Stokes equations for a perfect fluid. We validate the numerical algorithm by means of exact results for transition to convection in Rayleigh-Bénard compressible systems and against direct comparison with finite-difference schemes. The method is stable and reliable up to temperature jumps between top and bottom walls of the order of 50% the averaged bulk temperature. We use this method to study Rayleigh-Taylor instability for compressible stratified flows and we determine the growth of the mixing layer at changing Atwood numbers up to At ∼ 0.4. We highlight the role played by the adiabatic gradient in stopping the mixing layer growth in presence of high stratification and we quantify the asymmetric growth rate for spikes and bubbles for two dimensional RayleighTaylor systems with resolution up to Lx × Lz = 1664 × 4400 and with Rayleigh numbers up to Ra ∼ 2 × 10 10 .

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Non-Oberbeck-Boussinesq Effects in Gaseous Rayleigh-Bénard Convection

Cited by 67 publications

References 20 publications

New perspectives in turbulent Rayleigh-Bénard convection

New perspectives in turbulent Rayleigh-Bénard convection

Horizontal structures of velocity and temperature boundary layers in two-dimensional numerical turbulent Rayleigh-Bénard convection

Lattice Boltzmann methods for thermal flows: Continuum limit and applications to compressible Rayleigh–Taylor systems

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