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Rayleigh–Bénard convection

January 01, 1970

In fluid thermodynamics, Rayleigh–Bénard convection is a type of natural convection, occurring in a planar horizontal layer of fluid heated from below, in which the fluid develops a regular pattern of convection cells known as Bénard cells. Such systems were first investigated by Boussinesq[1] and Oberbeck[2] in the 19th century. This phenomenon can also manifest where a species denser than the electrolyte is consumed from below and generated at the top.[3] Bénard–Rayleigh convection is one of the most commonly studied convection phenomena because of its analytical and experimental accessibility.[4] The convection patterns are the most carefully examined example of self-organizing nonlinear systems.[4][5] Time-dependent self-similar analytic solutions are known for the velocity fields and for the temperature distribution as well.[6][7]

Bénard cells.

Buoyancy, and hence gravity, are responsible for the appearance of convection cells. The initial movement is the upwelling of less-dense fluid from the warmer bottom layer.[8] This upwelling spontaneously organizes into a regular pattern of cells.

Rayleigh–Bénard convection produces complex patterns of frost damage in grass.[9] Frost regions turn brown after several days while frost-free regions remain green. The spatial scale of the pattern is ~20cm.

Physical processes edit

The features of Bénard convection can be obtained by a simple experiment first conducted by Henri Bénard, a French physicist, in 1900.

Development of convection edit

 
Convection cells in a gravity field

The experimental set-up uses a layer of liquid, e.g. water, between two parallel planes. The height of the layer is small compared to the horizontal dimension. At first, the temperature of the bottom plane is the same as the top plane. The liquid will then tend towards an equilibrium, where its temperature is the same as its surroundings. (Once there, the liquid is perfectly uniform: to an observer it would appear the same from any position. This equilibrium is also asymptotically stable: after a local, temporary perturbation of the outside temperature, it will go back to its uniform state, in line with the second law of thermodynamics).

Then, the temperature of the bottom plane is increased slightly yielding a flow of thermal energy conducted through the liquid. The system will begin to have a structure of thermal conductivity: the temperature, and the density and pressure with it, will vary linearly between the bottom and top plane. A uniform linear gradient of temperature will be established. (This system may be modelled by statistical mechanics).

Once conduction is established, the microscopic random movement spontaneously becomes ordered on a macroscopic level, forming Benard convection cells, with a characteristic correlation length.

Convection features edit

 
Simulation of Rayleigh–Bénard convection in 3D.

The rotation of the cells is stable and will alternate from clock-wise to counter-clockwise horizontally; this is an example of spontaneous symmetry breaking. Bénard cells are metastable. This means that a small perturbation will not be able to change the rotation of the cells, but a larger one could affect the rotation; they exhibit a form of hysteresis.

Moreover, the deterministic law at the microscopic level produces a non-deterministic arrangement of the cells: if the experiment is repeated, a particular position in the experiment will be in a clockwise cell in some cases, and a counter-clockwise cell in others. Microscopic perturbations of the initial conditions are enough to produce a non-deterministic macroscopic effect. That is, in principle, there is no way to calculate the macroscopic effect of a microscopic perturbation. This inability to predict long-range conditions and sensitivity to initial-conditions are characteristics of chaotic or complex systems (i.e., the butterfly effect).

turbulent Rayleigh–Bénard convection

If the temperature of the bottom plane was to be further increased, the structure would become more complex in space and time; the turbulent flow would become chaotic.

Convective Bénard cells tend to approximate regular right hexagonal prisms, particularly in the absence of turbulence,[10][11][12] although certain experimental conditions can result in the formation of regular right square prisms[13] or spirals.[14]

The convective Bénard cells are not unique and will usually appear only in the surface tension driven convection. In general the solutions to the Rayleigh and Pearson[15] analysis (linear theory) assuming an infinite horizontal layer gives rise to degeneracy meaning that many patterns may be obtained by the system. Assuming uniform temperature at the top and bottom plates, when a realistic system is used (a layer with horizontal boundaries) the shape of the boundaries will mandate the pattern. More often than not the convection will appear as rolls or a superposition of them.

Rayleigh–Bénard instability edit

Since there is a density gradient between the top and the bottom plate, gravity acts trying to pull the cooler, denser liquid from the top to the bottom. This gravitational force is opposed by the viscous damping force in the fluid. The balance of these two forces is expressed by a non-dimensional parameter called the Rayleigh number. The Rayleigh number is defined as:

 

where

Tu is the temperature of the top plate
Tb is the temperature of the bottom plate
L is the height of the container
g is the acceleration due to gravity
ν is the kinematic viscosity
α is the thermal diffusivity
β is the thermal expansion coefficient.

As the Rayleigh number increases, the gravitational forces become more dominant. At a critical Rayleigh number of 1708,[5] instability sets in and convection cells appear.

The critical Rayleigh number can be obtained analytically for a number of different boundary conditions by doing a perturbation analysis on the linearized equations in the stable state.[16] The simplest case is that of two free boundaries, which Lord Rayleigh solved in 1916, obtaining Ra = 274 π4 ≈ 657.51.[17] In the case of a rigid boundary at the bottom and a free boundary at the top (as in the case of a kettle without a lid), the critical Rayleigh number comes out as Ra = 1,100.65.[18]

Effects of surface tension edit

Main article: Marangoni effect

In case of a free liquid surface in contact with air, buoyancy and surface tension effects will also play a role in how the convection patterns develop. Liquids flow from places of lower surface tension to places of higher surface tension. This is called the Marangoni effect. When applying heat from below, the temperature at the top layer will show temperature fluctuations. With increasing temperature, surface tension decreases. Thus a lateral flow of liquid at the surface will take place,[19] from warmer areas to cooler areas. In order to preserve a horizontal (or nearly horizontal) liquid surface, cooler surface liquid will descend. This down-welling of cooler liquid contributes to the driving force of the convection cells. The specific case of temperature gradient-driven surface tension variations is known as thermo-capillary convection, or Bénard–Marangoni convection.

History and nomenclature edit

In 1870, the Irish-Scottish physicist and engineer James Thomson (1822–1892), elder brother of Lord Kelvin, observed water cooling in a tub; he noted that the soapy film on the water's surface was divided as if the surface had been tiled (tesselated). In 1882, he showed that the tesselation was due to the presence of convection cells.[20] In 1900, the French physicist Henri Bénard (1874–1939) independently arrived at the same conclusion.[21] This pattern of convection, whose effects are due solely to a temperature gradient, was first successfully analyzed in 1916 by Lord Rayleigh (1842–1919).[22] Rayleigh assumed boundary conditions in which the vertical velocity component and temperature disturbance vanish at the top and bottom boundaries (perfect thermal conduction). Those assumptions resulted in the analysis losing any connection with Henri Bénard's experiment. This resulted in discrepancies between theoretical and experimental results until 1958, when John Pearson (1930– ) reworked the problem based on surface tension.[15] This is what was originally observed by Bénard. Nonetheless in modern usage "Rayleigh–Bénard convection" refers to the effects due to temperature, whereas "Bénard–Marangoni convection" refers specifically to the effects of surface tension.[4] Davis and Koschmieder have suggested that the convection should be rightfully called the "Pearson–Bénard convection".[5]

Rayleigh–Bénard convection is also sometimes known as "Bénard–Rayleigh convection", "Bénard convection", or "Rayleigh convection".

See also edit

References edit

  1. ^ Boussinesq, M.J. (1871). "Theorie de l'intumescence liquide appellée onde solitaire ou de translation, se propageant dans un canal rectangulaire". Comptes Rendus Acad. Sci. (Paris). 72: 755–759.
  2. ^ Oberbeck, A (1879). "Über die Wärmeleitung der Flüssigkeiten bei Berücksichtigung der Strömungen infolge von Temperaturdifferenzen". Ann. Phys. Chem. 7 (6): 271-292 |. doi:10.1002/andp.18792430606. JFM 11.0787.01.
  3. ^ Colli, A.N.; Bisang, J.M. (2023). "Exploring the Impact of Concentration and Temperature Variations on Transient Natural Convection in Metal Electrodeposition: A Finite Volume Method Analysis". Journal of the Electrochemical Society. 170 (8): 083505. Bibcode:2023JElS..170h3505C. doi:10.1149/1945-7111/acef62. S2CID 260857287.
  4. ^ a b c Getling, A. V. (1998). Bénard–Rayleigh Convection: Structures and Dynamics. World Scientific. ISBN 978-981-02-2657-2.
  5. ^ a b c Koschmieder, E. L. (1993). Bénard Cells and Taylor Vortices. Cambridge. ISBN 0521-40204-2.
  6. ^ Barna, I.F.; Mátyás, L. (2015). "Analytic self-similar solutions of the Oberbeck–Boussinesq equations". Chaos, Solitons and Fractals. 78: 249–255. arXiv:1502.05039. doi:10.1016/j.chaos.2015.08.002.
  7. ^ Barna, I.F.; Pocsai, M.A.; Lökös, S.; Mátyás, L. (2017). "Rayleigh–Bènard convection in the generalized Oberbeck–Boussinesq system". Chaos, Solitons and Fractals. 103: 336–341. arXiv:1701.01647. doi:10.1016/j.chaos.2017.06.024.
  8. ^ . UC San Diego, Department of Physics. Archived from the original on 22 February 2009.
  9. ^ Ackerson BJ, Beier RA, Martin DL. Ground level air convection produces frost damage patterns in turfgrass. Int J Biometeorol. 2015;59:1655. https://doi.org/10.1007/s00484-015-0972-3
  10. ^ Rayleigh–Benard Convection Cells, with photos, from the Environmental Technology Laboratory at the National Oceanic and Atmospheric Administration in the United States Department of Commerce.
  11. ^ . www.edata-center.com. Archived from the original on 2007-12-12.
  12. ^ Cerisier, P.; Porterie, B.; Kaiss, A.; Cordonnier, J. (September 2005). "Transport and sedimentation of solid particles in Bénard hexagonal cells". The European Physical Journal E. 18 (1): 85–93. Bibcode:2005EPJE...18...85C. doi:10.1140/epje/i2005-10033-7. PMID 16187000. S2CID 34172862. INIST 17287579.
  13. ^ Eckert, Kerstin; Bestehorn, Michael; Thess, André (1998). "Square cells in surface-tension-driven Bénard convection: experiment and theory". Journal of Fluid Mechanics. 356 (1): 155–197. Bibcode:1998JFM...356..155E. doi:10.1017/S0022112097007842. S2CID 121502253.
  14. ^ . www.psc.edu. Archived from the original on 1999-11-15.
  15. ^ a b Pearson, J.R.A. (1958). "On convection cells induced by surface tension". Journal of Fluid Mechanics. 4 (5): 489–500. Bibcode:1958JFM.....4..489P. doi:10.1017/S0022112058000616. S2CID 123404447.
  16. ^ . Archived from the original on 2020-12-03. Retrieved 2010-06-26.
  17. ^ . Archived from the original on 2020-12-03. Retrieved 2011-04-06.
  18. ^ . Archived from the original on 2020-12-03. Retrieved 2010-06-26.
  19. ^ Sen, Asok K.; Davis, Stephen H. (August 1982). "Steady thermocapillary flows in two-dimensional slots". Journal of Fluid Mechanics. 121 (–1): 163. Bibcode:1982JFM...121..163S. doi:10.1017/s0022112082001840. S2CID 120180067.
  20. ^ Thomson, James (1882). "On a changing tesselated structure in certain liquids". Proceedings of the Philosophical Society of Glasgow. 8 (2): 464–468.
  21. ^ Bénard, Henri (1900). "Les tourbillons cellulaires dans une nappe liquide" [Cellular vortices in a sheet of liquid]. Revue Générale des Sciences Pures et Appliquées (in French). 11: 1261–1271, 1309–1328.
  22. ^ Rayleigh, Lord (1916). "On the convective currents in a horizontal layer of fluid when the higher temperature is on the under side". Philosophical Magazine. 6th series. 32 (192): 529–546.

Further reading edit

  • B. Saltzman (ed., 1962). Selected Papers on the Theory of Thermal Convection, with Special Application to the Earth's Planetary Atmosphere (Dover).
  • Subrahmanyan Chandrasekhar (1982). Hydrodynamic and Hydromagnetic Stability (Dover). ISBN 0-486-64071-X
  • E.L. Koschmieder (1993). Bénard Cells and Taylor Vortices (Cambridge University Press). ISBN 9780521402040
  • A.V. Getling (1998). Rayleigh-Bénard Convection: Structures and Dynamics (World Scientific).
  • R. Meyer-Spasche (1999). Pattern Formation in Viscous Flows: The Taylor-Couette Problem and Rayleigh-Bénard Convection (    Birkhäuser Basel).
  • P.G. Drazin and W.H. Reid (2004). Hydrodynamic Stability, second edition (Cambridge University Press).
  • R. Kh. Zeytounian (2009). Convection in Fluids: A Rational Analysis and Asymptotic Modelling (Springer).
  • E.S.C. Ching (2014). Statistics and Scaling in Turbulent Rayleigh-Bénard Convection (Springer). ISBN 978-981-4560-22-1
  • D. Goluskin (2015). Internally Heated Convection and Rayleigh-Bénard Convection (Springer).ISBN 9783319239392

External links edit

 
Wikimedia Commons has media related to Rayleigh–Bénard convection.
  • A. Getling, O. Brausch: Cellular flow patterns
  • K. Daniels, B. Plapp, W.Pesch, O. Brausch, E. Bodenschatz: Undulation Chaos in inclined Layer Convection
  • Karen E. Daniels, Oliver Brausch, Werner Pesch, Eberhard Bodenschatz: Competition and bistability of ordered undulations and undulation chaos in inclined layer convection 2021-01-02 at the Wayback Machine (PDF; 608 kB)
  • P. Subramanian, O. Brausch, E. Bodenschatz, K. Daniels, T.Schneider W. Pesch: Spatio-temporal Patterns in Inclined Layer Convection (PDF; 5,3 MB)

January 01, 1970
rayleigh, bénard, convection, fluid, thermodynamics, type, natural, convection, occurring, planar, horizontal, layer, fluid, heated, from, below, which, fluid, develops, regular, pattern, convection, cells, known, bénard, cells, such, systems, were, first, inv. In fluid thermodynamics Rayleigh Benard convection is a type of natural convection occurring in a planar horizontal layer of fluid heated from below in which the fluid develops a regular pattern of convection cells known as Benard cells Such systems were first investigated by Boussinesq 1 and Oberbeck 2 in the 19th century This phenomenon can also manifest where a species denser than the electrolyte is consumed from below and generated at the top 3 Benard Rayleigh convection is one of the most commonly studied convection phenomena because of its analytical and experimental accessibility 4 The convection patterns are the most carefully examined example of self organizing nonlinear systems 4 5 Time dependent self similar analytic solutions are known for the velocity fields and for the temperature distribution as well 6 7 source source source source source source Benard cells Buoyancy and hence gravity are responsible for the appearance of convection cells The initial movement is the upwelling of less dense fluid from the warmer bottom layer 8 This upwelling spontaneously organizes into a regular pattern of cells Rayleigh Benard convection produces complex patterns of frost damage in grass 9 Frost regions turn brown after several days while frost free regions remain green The spatial scale of the pattern is 20cm Contents 1 Physical processes 1 1 Development of convection 1 2 Convection features 2 Rayleigh Benard instability 3 Effects of surface tension 4 History and nomenclature 5 See also 6 References 7 Further reading 8 External linksPhysical processes editThe features of Benard convection can be obtained by a simple experiment first conducted by Henri Benard a French physicist in 1900 Development of convection edit nbsp Convection cells in a gravity field The experimental set up uses a layer of liquid e g water between two parallel planes The height of the layer is small compared to the horizontal dimension At first the temperature of the bottom plane is the same as the top plane The liquid will then tend towards an equilibrium where its temperature is the same as its surroundings Once there the liquid is perfectly uniform to an observer it would appear the same from any position This equilibrium is also asymptotically stable after a local temporary perturbation of the outside temperature it will go back to its uniform state in line with the second law of thermodynamics Then the temperature of the bottom plane is increased slightly yielding a flow of thermal energy conducted through the liquid The system will begin to have a structure of thermal conductivity the temperature and the density and pressure with it will vary linearly between the bottom and top plane A uniform linear gradient of temperature will be established This system may be modelled by statistical mechanics Once conduction is established the microscopic random movement spontaneously becomes ordered on a macroscopic level forming Benard convection cells with a characteristic correlation length Convection features edit nbsp Simulation of Rayleigh Benard convection in 3D The rotation of the cells is stable and will alternate from clock wise to counter clockwise horizontally this is an example of spontaneous symmetry breaking Benard cells are metastable This means that a small perturbation will not be able to change the rotation of the cells but a larger one could affect the rotation they exhibit a form of hysteresis Moreover the deterministic law at the microscopic level produces a non deterministic arrangement of the cells if the experiment is repeated a particular position in the experiment will be in a clockwise cell in some cases and a counter clockwise cell in others Microscopic perturbations of the initial conditions are enough to produce a non deterministic macroscopic effect That is in principle there is no way to calculate the macroscopic effect of a microscopic perturbation This inability to predict long range conditions and sensitivity to initial conditions are characteristics of chaotic or complex systems i e the butterfly effect source source source source source source source source turbulent Rayleigh Benard convection If the temperature of the bottom plane was to be further increased the structure would become more complex in space and time the turbulent flow would become chaotic Convective Benard cells tend to approximate regular right hexagonal prisms particularly in the absence of turbulence 10 11 12 although certain experimental conditions can result in the formation of regular right square prisms 13 or spirals 14 The convective Benard cells are not unique and will usually appear only in the surface tension driven convection In general the solutions to the Rayleigh and Pearson 15 analysis linear theory assuming an infinite horizontal layer gives rise to degeneracy meaning that many patterns may be obtained by the system Assuming uniform temperature at the top and bottom plates when a realistic system is used a layer with horizontal boundaries the shape of the boundaries will mandate the pattern More often than not the convection will appear as rolls or a superposition of them Rayleigh Benard instability editSince there is a density gradient between the top and the bottom plate gravity acts trying to pull the cooler denser liquid from the top to the bottom This gravitational force is opposed by the viscous damping force in the fluid The balance of these two forces is expressed by a non dimensional parameter called the Rayleigh number The Rayleigh number is defined as R a L g b n a T b T u L 3 displaystyle mathrm Ra L frac g beta nu alpha T b T u L 3 nbsp where Tu is the temperature of the top plate Tb is the temperature of the bottom plate L is the height of the container g is the acceleration due to gravity n is the kinematic viscosity a is the thermal diffusivity b is the thermal expansion coefficient As the Rayleigh number increases the gravitational forces become more dominant At a critical Rayleigh number of 1708 5 instability sets in and convection cells appear The critical Rayleigh number can be obtained analytically for a number of different boundary conditions by doing a perturbation analysis on the linearized equations in the stable state 16 The simplest case is that of two free boundaries which Lord Rayleigh solved in 1916 obtaining Ra 27 4 p4 657 51 17 In the case of a rigid boundary at the bottom and a free boundary at the top as in the case of a kettle without a lid the critical Rayleigh number comes out as Ra 1 100 65 18 Effects of surface tension editMain article Marangoni effect In case of a free liquid surface in contact with air buoyancy and surface tension effects will also play a role in how the convection patterns develop Liquids flow from places of lower surface tension to places of higher surface tension This is called the Marangoni effect When applying heat from below the temperature at the top layer will show temperature fluctuations With increasing temperature surface tension decreases Thus a lateral flow of liquid at the surface will take place 19 from warmer areas to cooler areas In order to preserve a horizontal or nearly horizontal liquid surface cooler surface liquid will descend This down welling of cooler liquid contributes to the driving force of the convection cells The specific case of temperature gradient driven surface tension variations is known as thermo capillary convection or Benard Marangoni convection History and nomenclature editIn 1870 the Irish Scottish physicist and engineer James Thomson 1822 1892 elder brother of Lord Kelvin observed water cooling in a tub he noted that the soapy film on the water s surface was divided as if the surface had been tiled tesselated In 1882 he showed that the tesselation was due to the presence of convection cells 20 In 1900 the French physicist Henri Benard 1874 1939 independently arrived at the same conclusion 21 This pattern of convection whose effects are due solely to a temperature gradient was first successfully analyzed in 1916 by Lord Rayleigh 1842 1919 22 Rayleigh assumed boundary conditions in which the vertical velocity component and temperature disturbance vanish at the top and bottom boundaries perfect thermal conduction Those assumptions resulted in the analysis losing any connection with Henri Benard s experiment This resulted in discrepancies between theoretical and experimental results until 1958 when John Pearson 1930 reworked the problem based on surface tension 15 This is what was originally observed by Benard Nonetheless in modern usage Rayleigh Benard convection refers to the effects due to temperature whereas Benard Marangoni convection refers specifically to the effects of surface tension 4 Davis and Koschmieder have suggested that the convection should be rightfully called the Pearson Benard convection 5 Rayleigh Benard convection is also sometimes known as Benard Rayleigh convection Benard convection or Rayleigh convection See also editHydrodynamic stability Marangoni effect Natural convection Giant s Causeway and Causeway Coast Rayleigh Taylor instabilityReferences edit Boussinesq M J 1871 Theorie de l intumescence liquide appellee onde solitaire ou de translation se propageant dans un canal rectangulaire Comptes Rendus Acad Sci Paris 72 755 759 Oberbeck A 1879 Uber die Warmeleitung der Flussigkeiten bei Berucksichtigung der Stromungen infolge von Temperaturdifferenzen Ann Phys Chem 7 6 271 292 doi 10 1002 andp 18792430606 JFM 11 0787 01 Colli A N Bisang J M 2023 Exploring the Impact of Concentration and Temperature Variations on Transient Natural Convection in Metal Electrodeposition A Finite Volume Method Analysis Journal of the Electrochemical Society 170 8 083505 Bibcode 2023JElS 170h3505C doi 10 1149 1945 7111 acef62 S2CID 260857287 a b c Getling A V 1998 Benard Rayleigh Convection Structures and Dynamics World Scientific ISBN 978 981 02 2657 2 a b c Koschmieder E L 1993 Benard Cells and Taylor Vortices Cambridge ISBN 0521 40204 2 Barna I F Matyas L 2015 Analytic self similar solutions of the Oberbeck Boussinesq equations Chaos Solitons and Fractals 78 249 255 arXiv 1502 05039 doi 10 1016 j chaos 2015 08 002 Barna I F Pocsai M A Lokos S Matyas L 2017 Rayleigh Benard convection in the generalized Oberbeck Boussinesq system Chaos Solitons and Fractals 103 336 341 arXiv 1701 01647 doi 10 1016 j chaos 2017 06 024 Rayleigh Benard Convection UC San Diego Department of Physics Archived from the original on 22 February 2009 Ackerson BJ Beier RA Martin DL Ground level air convection produces frost damage patterns in turfgrass Int J Biometeorol 2015 59 1655 https doi org 10 1007 s00484 015 0972 3 Rayleigh Benard Convection Cells with photos from the Environmental Technology Laboratory at the National Oceanic and Atmospheric Administration in the United States Department of Commerce DIRECT NUMERICAL SIMULATION OF BENARD MARANGONI CONVECTION www edata center com Archived from the original on 2007 12 12 Cerisier P Porterie B Kaiss A Cordonnier J September 2005 Transport and sedimentation of solid particles in Benard hexagonal cells The European Physical Journal E 18 1 85 93 Bibcode 2005EPJE 18 85C doi 10 1140 epje i2005 10033 7 PMID 16187000 S2CID 34172862 INIST 17287579 Eckert Kerstin Bestehorn Michael Thess Andre 1998 Square cells in surface tension driven Benard convection experiment and theory Journal of Fluid Mechanics 356 1 155 197 Bibcode 1998JFM 356 155E doi 10 1017 S0022112097007842 S2CID 121502253 SPIRAL CHAOS Simulating Rayleigh Benard Convection www psc edu Archived from the original on 1999 11 15 a b Pearson J R A 1958 On convection cells induced by surface tension Journal of Fluid Mechanics 4 5 489 500 Bibcode 1958JFM 4 489P doi 10 1017 S0022112058000616 S2CID 123404447 Rayleigh Benard Convection Archived from the original on 2020 12 03 Retrieved 2010 06 26 Free free boundaries Archived from the original on 2020 12 03 Retrieved 2011 04 06 Rigid free boundary Archived from the original on 2020 12 03 Retrieved 2010 06 26 Sen Asok K Davis Stephen H August 1982 Steady thermocapillary flows in two dimensional slots Journal of Fluid Mechanics 121 1 163 Bibcode 1982JFM 121 163S doi 10 1017 s0022112082001840 S2CID 120180067 Thomson James 1882 On a changing tesselated structure in certain liquids Proceedings of the Philosophical Society of Glasgow 8 2 464 468 Benard Henri 1900 Les tourbillons cellulaires dans une nappe liquide Cellular vortices in a sheet of liquid Revue Generale des Sciences Pures et Appliquees in French 11 1261 1271 1309 1328 Rayleigh Lord 1916 On the convective currents in a horizontal layer of fluid when the higher temperature is on the under side Philosophical Magazine 6th series 32 192 529 546 Further reading editB Saltzman ed 1962 Selected Papers on the Theory of Thermal Convection with Special Application to the Earth s Planetary Atmosphere Dover Subrahmanyan Chandrasekhar 1982 Hydrodynamic and Hydromagnetic Stability Dover ISBN 0 486 64071 X E L Koschmieder 1993 Benard Cells and Taylor Vortices Cambridge University Press ISBN 9780521402040 A V Getling 1998 Rayleigh Benard Convection Structures and Dynamics World Scientific R Meyer Spasche 1999 Pattern Formation in Viscous Flows The Taylor Couette Problem and Rayleigh Benard Convection Birkhauser Basel P G Drazin and W H Reid 2004 Hydrodynamic Stability second edition Cambridge University Press R Kh Zeytounian 2009 Convection in Fluids A Rational Analysis and Asymptotic Modelling Springer E S C Ching 2014 Statistics and Scaling in Turbulent Rayleigh Benard Convection Springer ISBN 978 981 4560 22 1 D Goluskin 2015 Internally Heated Convection and Rayleigh Benard Convection Springer ISBN 9783319239392External links edit nbsp Wikimedia Commons has media related to Rayleigh Benard convection A Getling O Brausch Cellular flow patterns K Daniels B Plapp W Pesch O Brausch E Bodenschatz Undulation Chaos in inclined Layer Convection Karen E Daniels Oliver Brausch Werner Pesch Eberhard Bodenschatz Competition and bistability of ordered undulations and undulation chaos in inclined layer convection Archived 2021 01 02 at the Wayback Machine PDF 608 kB P Subramanian O Brausch E Bodenschatz K Daniels T Schneider W Pesch Spatio temporal Patterns in Inclined Layer Convection PDF 5 3 MB Retrieved from https en wikipedia org w index php title Rayleigh Benard convection amp oldid 1224598023, wikipedia, wiki, book, books, library,

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