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Young–Laplace equation

November 13, 2023

Not to be confused with Young's equation for surface wetting or Laplace's equation.

In physics, the Young–Laplace equation (/ləˈplɑːs/) is an algebraic equation that describes the capillary pressure difference sustained across the interface between two static fluids, such as water and air, due to the phenomenon of surface tension or wall tension, although use of the latter is only applicable if assuming that the wall is very thin. The Young–Laplace equation relates the pressure difference to the shape of the surface or wall and it is fundamentally important in the study of static capillary surfaces. It's a statement of normal stress balance for static fluids meeting at an interface, where the interface is treated as a surface (zero thickness):

where is the Laplace pressure, the pressure difference across the fluid interface (the exterior pressure minus the interior pressure), is the surface tension (or wall tension), is the unit normal pointing out of the surface, is the mean curvature, and and are the principal radii of curvature. Note that only normal stress is considered, this is because it has been shown[1] that a static interface is possible only in the absence of tangential stress.

The equation is named after Thomas Young, who developed the qualitative theory of surface tension in 1805, and Pierre-Simon Laplace who completed the mathematical description in the following year. It is sometimes also called the Young–Laplace–Gauss equation, as Carl Friedrich Gauss unified the work of Young and Laplace in 1830, deriving both the differential equation and boundary conditions using Johann Bernoulli's virtual work principles.[2]

Soap films edit

Main article: Soap film

If the pressure difference is zero, as in a soap film without gravity, the interface will assume the shape of a minimal surface.

Emulsions edit

The equation also explains the energy required to create an emulsion. To form the small, highly curved droplets of an emulsion, extra energy is required to overcome the large pressure that results from their small radius.

The Laplace pressure, which is greater for smaller droplets, causes the diffusion of molecules out of the smallest droplets in an emulsion and drives emulsion coarsening via Ostwald ripening.[citation needed]

Capillary pressure in a tube edit

 
Spherical meniscus with wetting angle less than 90°

In a sufficiently narrow (i.e., low Bond number) tube of circular cross-section (radius a), the interface between two fluids forms a meniscus that is a portion of the surface of a sphere with radius R. The pressure jump across this surface is related to the radius and the surface tension γ by

 

This may be shown by writing the Young–Laplace equation in spherical form with a contact angle boundary condition and also a prescribed height boundary condition at, say, the bottom of the meniscus. The solution is a portion of a sphere, and the solution will exist only for the pressure difference shown above. This is significant because there isn't another equation or law to specify the pressure difference; existence of solution for one specific value of the pressure difference prescribes it.

The radius of the sphere will be a function only of the contact angle, θ, which in turn depends on the exact properties of the fluids and the container material with which the fluids in question are contacting/interfacing:

 

so that the pressure difference may be written as:

 
 
Illustration of capillary rise. Red=contact angle less than 90°; blue=contact angle greater than 90°

In order to maintain hydrostatic equilibrium, the induced capillary pressure is balanced by a change in height, h, which can be positive or negative, depending on whether the wetting angle is less than or greater than 90°. For a fluid of density ρ:

 
where g is the gravitational acceleration. This is sometimes known as the Jurin's law or Jurin height[3] after James Jurin who studied the effect in 1718.[4]

For a water-filled glass tube in air at sea level:

  • γ = 0.0728 J/m2 at 20 °C
  • θ = 20° (0.35 rad)
  • ρ = 1000 kg/m3
  • g = 9.8 m/s2

and so the height of the water column is given by:

 
Thus for a 2 mm wide (1 mm radius) tube, the water would rise 14 mm. However, for a capillary tube with radius 0.1 mm, the water would rise 14 cm (about 6 inches).

Capillary action in general edit

In the general case, for a free surface and where there is an applied "over-pressure", Δp, at the interface in equilibrium, there is a balance between the applied pressure, the hydrostatic pressure and the effects of surface tension. The Young–Laplace equation becomes:

 

The equation can be non-dimensionalised in terms of its characteristic length-scale, the capillary length:

 
and characteristic pressure
 

For clean water at standard temperature and pressure, the capillary length is ~2 mm.

The non-dimensional equation then becomes:

 

Thus, the surface shape is determined by only one parameter, the over pressure of the fluid, Δp* and the scale of the surface is given by the capillary length. The solution of the equation requires an initial condition for position, and the gradient of the surface at the start point.

 
A pendant drop is produced for an over pressure of Δp*=3 and initial condition r0=10−4, z0=0, dz/dr=0
 
A liquid bridge is produced for an over pressure of Δp*=3.5 and initial condition r0=0.25−4, z0=0, dz/dr=0

Axisymmetric equations edit

The (nondimensional) shape, r(z) of an axisymmetric surface can be found by substituting general expressions for principal curvatures to give the hydrostatic Young–Laplace equations:[5]

 
 

Application in medicine edit

In medicine it is often referred to as the Law of Laplace, used in the context of cardiovascular physiology,[6] and also respiratory physiology, though the latter use is often erroneous.[7]

History edit

Francis Hauksbee performed some of the earliest observations and experiments in 1709[8] and these were repeated in 1718 by James Jurin who observed that the height of fluid in a capillary column was a function only of the cross-sectional area at the surface, not of any other dimensions of the column.[4][9]

Thomas Young laid the foundations of the equation in his 1804 paper An Essay on the Cohesion of Fluids[10] where he set out in descriptive terms the principles governing contact between fluids (along with many other aspects of fluid behaviour). Pierre Simon Laplace followed this up in Mécanique Céleste[11] with the formal mathematical description given above, which reproduced in symbolic terms the relationship described earlier by Young.

Laplace accepted the idea propounded by Hauksbee in his book Physico-mechanical Experiments (1709), that the phenomenon was due to a force of attraction that was insensible at sensible distances.[12][13] The part which deals with the action of a solid on a liquid and the mutual action of two liquids was not worked out thoroughly, but ultimately was completed by Carl Friedrich Gauss.[14] Franz Ernst Neumann (1798-1895) later filled in a few details.[15][9][16]

References edit

  1. ^ Surface Tension Module 2007-10-27 at the Wayback Machine, by John W. M. Bush, at MIT OCW.
  2. ^ Robert Finn (1999). "Capillary Surface Interfaces" (PDF). AMS.
  3. ^ "Jurin rule". McGraw-Hill Dictionary of Scientific and Technical Terms. McGraw-Hill on Answers.com. 2003. Retrieved 2007-09-05.
  4. ^ a b See:
    • James Jurin (1718) "An account of some experiments shown before the Royal Society; with an enquiry into the cause of some of the ascent and suspension of water in capillary tubes," Philosophical Transactions of the Royal Society of London, 30 : 739–747.
    • James Jurin (1719) "An account of some new experiments, relating to the action of glass tubes upon water and quicksilver," Philosophical Transactions of the Royal Society of London, 30 : 1083–1096.
  5. ^ Lamb, H. Statics, Including Hydrostatics and the Elements of the Theory of Elasticity, 3rd ed. Cambridge, England: Cambridge University Press, 1928.
  6. ^ Basford, Jeffrey R. (2002). "The Law of Laplace and its relevance to contemporary medicine and rehabilitation". Archives of Physical Medicine and Rehabilitation. 83 (8): 1165–1170. doi:10.1053/apmr.2002.33985. PMID 12161841.
  7. ^ Prange, Henry D. (2003). "Laplace's Law and the Alveolus: A Misconception of Anatomy and a Misapplication of Physics". Advances in Physiology Education. 27 (1): 34–40. doi:10.1152/advan.00024.2002. PMID 12594072. S2CID 7791096.
  8. ^ See:
    • Francis Hauksbee, Physico-mechanical Experiments on Various Subjects … (London, England: (Self-published by author; printed by R. Brugis), 1709), pages 139–169.
    • Francis Hauksbee (1711) "An account of an experiment touching the direction of a drop of oil of oranges, between two glass planes, towards any side of them that is nearest press'd together," Philosophical Transactions of the Royal Society of London, 27 : 374–375.
    • Francis Hauksbee (1712) "An account of an experiment touching the ascent of water between two glass planes, in an hyperbolick figure," Philosophical Transactions of the Royal Society of London, 27 : 539–540.
  9. ^ a b Maxwell, James Clerk; Strutt, John William (1911). "Capillary Action" . Encyclopædia Britannica. Vol. 5 (11th ed.). pp. 256–275.
  10. ^ Thomas Young (1805) "An essay on the cohesion of fluids," Philosophical Transactions of the Royal Society of London, 95 : 65–87.
  11. ^ Pierre Simon marquis de Laplace, Traité de Mécanique Céleste, volume 4, (Paris, France: Courcier, 1805), Supplément au dixième livre du Traité de Mécanique Céleste, pages 1–79.
  12. ^ Pierre Simon marquis de Laplace, Traité de Mécanique Céleste, volume 4, (Paris, France: Courcier, 1805), Supplément au dixième livre du Traité de Mécanique Céleste. On page 2 of the Supplément, Laplace states that capillary action is due to "… les lois dans lesquelles l'attraction n'est sensible qu'à des distances insensibles; …" (… the laws in which attraction is sensible [significant] only at insensible [infinitesimal] distances …).
  13. ^ In 1751, Johann Andreas Segner came to the same conclusion that Hauksbee had reached in 1709: J. A. von Segner (1751) "De figuris superficierum fluidarum" (On the shapes of liquid surfaces), Commentarii Societatis Regiae Scientiarum Gottingensis (Memoirs of the Royal Scientific Society at Göttingen), 1 : 301–372. On page 303, Segner proposes that liquids are held together by an attractive force (vim attractricem) that acts over such short distances "that no one could yet have perceived it with their senses" (… ut nullo adhuc sensu percipi poterit.).
  14. ^ Carl Friedrich Gauss, Principia generalia Theoriae Figurae Fluidorum in statu Aequilibrii [General principles of the theory of fluid shapes in a state of equilibrium] (Göttingen, (Germany): Dieterichs, 1830). Available on-line at: Hathi Trust.
  15. ^ Franz Neumann with A. Wangerin, ed., Vorlesungen über die Theorie der Capillarität [Lectures on the theory of capillarity] (Leipzig, Germany: B. G. Teubner, 1894).
  16. ^ Rouse Ball, W. W. [1908] (2003) "Pierre Simon Laplace (1749–1827)", in A Short Account of the History of Mathematics, 4th ed., Dover, ISBN 0-486-20630-0

Further reading edit

  • Maxwell, James Clerk; Strutt, John William (1911). "Capillary Action" . In Chisholm, Hugh (ed.). Encyclopædia Britannica. Vol. 5 (11th ed.). Cambridge University Press. pp. 256–275.
  • Batchelor, G. K. (1967) An Introduction To Fluid Dynamics, Cambridge University Press
  • Jurin, J. (1716). "An account of some experiments shown before the Royal Society; with an enquiry into the cause of the ascent and suspension of water in capillary tubes". Philosophical Transactions of the Royal Society. 30 (351–363): 739–747. doi:10.1098/rstl.1717.0026. S2CID 186211806.
  • Tadros T. F. (1995) Surfactants in Agrochemicals, Surfactant Science series, vol.54, Dekker

November 13, 2023
young, laplace, equation, confused, with, young, equation, surface, wetting, laplace, equation, physics, ɑː, algebraic, equation, that, describes, capillary, pressure, difference, sustained, across, interface, between, static, fluids, such, water, phenomenon, . Not to be confused with Young s equation for surface wetting or Laplace s equation In physics the Young Laplace equation l e ˈ p l ɑː s is an algebraic equation that describes the capillary pressure difference sustained across the interface between two static fluids such as water and air due to the phenomenon of surface tension or wall tension although use of the latter is only applicable if assuming that the wall is very thin The Young Laplace equation relates the pressure difference to the shape of the surface or wall and it is fundamentally important in the study of static capillary surfaces It s a statement of normal stress balance for static fluids meeting at an interface where the interface is treated as a surface zero thickness D p g n 2 g H f g 1 R 1 1 R 2 displaystyle begin aligned Delta p amp gamma nabla cdot hat n amp 2 gamma H f amp gamma left frac 1 R 1 frac 1 R 2 right end aligned where D p displaystyle Delta p is the Laplace pressure the pressure difference across the fluid interface the exterior pressure minus the interior pressure g displaystyle gamma is the surface tension or wall tension n displaystyle hat n is the unit normal pointing out of the surface H f displaystyle H f is the mean curvature and R 1 displaystyle R 1 and R 2 displaystyle R 2 are the principal radii of curvature Note that only normal stress is considered this is because it has been shown 1 that a static interface is possible only in the absence of tangential stress The equation is named after Thomas Young who developed the qualitative theory of surface tension in 1805 and Pierre Simon Laplace who completed the mathematical description in the following year It is sometimes also called the Young Laplace Gauss equation as Carl Friedrich Gauss unified the work of Young and Laplace in 1830 deriving both the differential equation and boundary conditions using Johann Bernoulli s virtual work principles 2 Contents 1 Soap films 2 Emulsions 3 Capillary pressure in a tube 4 Capillary action in general 4 1 Axisymmetric equations 5 Application in medicine 6 History 7 References 8 Further readingSoap films editMain article Soap film If the pressure difference is zero as in a soap film without gravity the interface will assume the shape of a minimal surface Emulsions editThe equation also explains the energy required to create an emulsion To form the small highly curved droplets of an emulsion extra energy is required to overcome the large pressure that results from their small radius The Laplace pressure which is greater for smaller droplets causes the diffusion of molecules out of the smallest droplets in an emulsion and drives emulsion coarsening via Ostwald ripening citation needed Capillary pressure in a tube edit nbsp Spherical meniscus with wetting angle less than 90 In a sufficiently narrow i e low Bond number tube of circular cross section radius a the interface between two fluids forms a meniscus that is a portion of the surface of a sphere with radius R The pressure jump across this surface is related to the radius and the surface tension g byD p 2 g R displaystyle Delta p frac 2 gamma R nbsp This may be shown by writing the Young Laplace equation in spherical form with a contact angle boundary condition and also a prescribed height boundary condition at say the bottom of the meniscus The solution is a portion of a sphere and the solution will exist only for the pressure difference shown above This is significant because there isn t another equation or law to specify the pressure difference existence of solution for one specific value of the pressure difference prescribes it The radius of the sphere will be a function only of the contact angle 8 which in turn depends on the exact properties of the fluids and the container material with which the fluids in question are contacting interfacing R a cos 8 displaystyle R frac a cos theta nbsp so that the pressure difference may be written as D p 2 g cos 8 a displaystyle Delta p frac 2 gamma cos theta a nbsp nbsp Illustration of capillary rise Red contact angle less than 90 blue contact angle greater than 90 In order to maintain hydrostatic equilibrium the induced capillary pressure is balanced by a change in height h which can be positive or negative depending on whether the wetting angle is less than or greater than 90 For a fluid of density r r g h 2 g cos 8 a displaystyle rho gh frac 2 gamma cos theta a nbsp where g is the gravitational acceleration This is sometimes known as the Jurin s law or Jurin height 3 after James Jurin who studied the effect in 1718 4 For a water filled glass tube in air at sea level g 0 0728 J m2 at 20 C 8 20 0 35 rad r 1000 kg m3 g 9 8 m s2and so the height of the water column is given by h 1 4 10 5 m a displaystyle h approx 1 4 times 10 5 mathrm m over a nbsp Thus for a 2 mm wide 1 mm radius tube the water would rise 14 mm However for a capillary tube with radius 0 1 mm the water would rise 14 cm about 6 inches Capillary action in general editIn the general case for a free surface and where there is an applied over pressure Dp at the interface in equilibrium there is a balance between the applied pressure the hydrostatic pressure and the effects of surface tension The Young Laplace equation becomes D p r g h g 1 R 1 1 R 2 displaystyle Delta p rho gh gamma left frac 1 R 1 frac 1 R 2 right nbsp The equation can be non dimensionalised in terms of its characteristic length scale the capillary length L c g r g displaystyle L c sqrt frac gamma rho g nbsp and characteristic pressure p c g L c g r g displaystyle p c frac gamma L c sqrt gamma rho g nbsp For clean water at standard temperature and pressure the capillary length is 2 mm The non dimensional equation then becomes h D p 1 R 1 1 R 2 displaystyle h Delta p left frac 1 R 1 frac 1 R 2 right nbsp Thus the surface shape is determined by only one parameter the over pressure of the fluid Dp and the scale of the surface is given by the capillary length The solution of the equation requires an initial condition for position and the gradient of the surface at the start point nbsp A pendant drop is produced for an over pressure of Dp 3 and initial condition r0 10 4 z0 0 dz dr 0 nbsp A liquid bridge is produced for an over pressure of Dp 3 5 and initial condition r0 0 25 4 z0 0 dz dr 0 Axisymmetric equations edit The nondimensional shape r z of an axisymmetric surface can be found by substituting general expressions for principal curvatures to give the hydrostatic Young Laplace equations 5 r 1 r 2 3 2 1 r z 1 r 2 z D p displaystyle frac r 1 r 2 3 2 frac 1 r z sqrt 1 r 2 z Delta p nbsp z 1 z 2 3 2 z r 1 z 2 1 2 D p z r displaystyle frac z 1 z 2 3 2 frac z r 1 z 2 1 2 Delta p z r nbsp Application in medicine editIn medicine it is often referred to as the Law of Laplace used in the context of cardiovascular physiology 6 and also respiratory physiology though the latter use is often erroneous 7 History editFrancis Hauksbee performed some of the earliest observations and experiments in 1709 8 and these were repeated in 1718 by James Jurin who observed that the height of fluid in a capillary column was a function only of the cross sectional area at the surface not of any other dimensions of the column 4 9 Thomas Young laid the foundations of the equation in his 1804 paper An Essay on the Cohesion of Fluids 10 where he set out in descriptive terms the principles governing contact between fluids along with many other aspects of fluid behaviour Pierre Simon Laplace followed this up in Mecanique Celeste 11 with the formal mathematical description given above which reproduced in symbolic terms the relationship described earlier by Young Laplace accepted the idea propounded by Hauksbee in his book Physico mechanical Experiments 1709 that the phenomenon was due to a force of attraction that was insensible at sensible distances 12 13 The part which deals with the action of a solid on a liquid and the mutual action of two liquids was not worked out thoroughly but ultimately was completed by Carl Friedrich Gauss 14 Franz Ernst Neumann 1798 1895 later filled in a few details 15 9 16 References edit Surface Tension Module Archived 2007 10 27 at the Wayback Machine by John W M Bush at MIT OCW Robert Finn 1999 Capillary Surface Interfaces PDF AMS Jurin rule McGraw Hill Dictionary of Scientific and Technical Terms McGraw Hill on Answers com 2003 Retrieved 2007 09 05 a b See James Jurin 1718 An account of some experiments shown before the Royal Society with an enquiry into the cause of some of the ascent and suspension of water in capillary tubes Philosophical Transactions of the Royal Society of London 30 739 747 James Jurin 1719 An account of some new experiments relating to the action of glass tubes upon water and quicksilver Philosophical Transactions of the Royal Society of London 30 1083 1096 Lamb H Statics Including Hydrostatics and the Elements of the Theory of Elasticity 3rd ed Cambridge England Cambridge University Press 1928 Basford Jeffrey R 2002 The Law of Laplace and its relevance to contemporary medicine and rehabilitation Archives of Physical Medicine and Rehabilitation 83 8 1165 1170 doi 10 1053 apmr 2002 33985 PMID 12161841 Prange Henry D 2003 Laplace s Law and the Alveolus A Misconception of Anatomy and a Misapplication of Physics Advances in Physiology Education 27 1 34 40 doi 10 1152 advan 00024 2002 PMID 12594072 S2CID 7791096 See Francis Hauksbee Physico mechanical Experiments on Various Subjects London England Self published by author printed by R Brugis 1709 pages 139 169 Francis Hauksbee 1711 An account of an experiment touching the direction of a drop of oil of oranges between two glass planes towards any side of them that is nearest press d together Philosophical Transactions of the Royal Society of London 27 374 375 Francis Hauksbee 1712 An account of an experiment touching the ascent of water between two glass planes in an hyperbolick figure Philosophical Transactions of the Royal Society of London 27 539 540 a b Maxwell James Clerk Strutt John William 1911 Capillary Action Encyclopaedia Britannica Vol 5 11th ed pp 256 275 Thomas Young 1805 An essay on the cohesion of fluids Philosophical Transactions of the Royal Society of London 95 65 87 Pierre Simon marquis de Laplace Traite de Mecanique Celeste volume 4 Paris France Courcier 1805 Supplement au dixieme livre du Traite de Mecanique Celeste pages 1 79 Pierre Simon marquis de Laplace Traite de Mecanique Celeste volume 4 Paris France Courcier 1805 Supplement au dixieme livre du Traite de Mecanique Celeste On page 2 of the Supplement Laplace states that capillary action is due to les lois dans lesquelles l attraction n est sensible qu a des distances insensibles the laws in which attraction is sensible significant only at insensible infinitesimal distances In 1751 Johann Andreas Segner came to the same conclusion that Hauksbee had reached in 1709 J A von Segner 1751 De figuris superficierum fluidarum On the shapes of liquid surfaces Commentarii Societatis Regiae Scientiarum Gottingensis Memoirs of the Royal Scientific Society at Gottingen 1 301 372 On page 303 Segner proposes that liquids are held together by an attractive force vim attractricem that acts over such short distances that no one could yet have perceived it with their senses ut nullo adhuc sensu percipi poterit Carl Friedrich Gauss Principia generalia Theoriae Figurae Fluidorum in statu Aequilibrii General principles of the theory of fluid shapes in a state of equilibrium Gottingen Germany Dieterichs 1830 Available on line at Hathi Trust Franz Neumann with A Wangerin ed Vorlesungen uber die Theorie der Capillaritat Lectures on the theory of capillarity Leipzig Germany B G Teubner 1894 Rouse Ball W W 1908 2003 Pierre Simon Laplace 1749 1827 in A Short Account of the History of Mathematics 4th ed Dover ISBN 0 486 20630 0Further reading editMaxwell James Clerk Strutt John William 1911 Capillary Action In Chisholm Hugh ed Encyclopaedia Britannica Vol 5 11th ed Cambridge University Press pp 256 275 Batchelor G K 1967 An Introduction To Fluid Dynamics Cambridge University Press Jurin J 1716 An account of some experiments shown before the Royal Society with an enquiry into the cause of the ascent and suspension of water in capillary tubes Philosophical Transactions of the Royal Society 30 351 363 739 747 doi 10 1098 rstl 1717 0026 S2CID 186211806 Tadros T F 1995 Surfactants in Agrochemicals Surfactant Science series vol 54 Dekker Retrieved from https en wikipedia org w index php title Young Laplace equation amp oldid 1169332042, wikipedia, wiki, book, books, library,

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