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Mechanical explanations of gravitation

January 29, 2023

Mechanical explanations of gravitation (or kinetic theories of gravitation) are attempts to explain the action of gravity by aid of basic mechanical processes, such as pressure forces caused by pushes, without the use of any action at a distance. These theories were developed from the 16th until the 19th century in connection with the aether. However, such models are no longer regarded as viable theories within the mainstream scientific community and general relativity is now the standard model to describe gravitation without the use of actions at a distance. Modern "quantum gravity" hypotheses also attempt to describe gravity by more fundamental processes such as particle fields, but they are not based on classical mechanics.

Screening

Main article: Le Sage's theory of gravitation

This theory is probably[1] the best-known mechanical explanation, and was developed for the first time by Nicolas Fatio de Duillier in 1690, and re-invented, among others, by Georges-Louis Le Sage (1748), Lord Kelvin (1872), and Hendrik Lorentz (1900), and criticized by James Clerk Maxwell (1875), and Henri Poincaré (1908).

The theory posits that the force of gravity is the result of tiny particles or waves moving at high speed in all directions, throughout the universe. The intensity of the flux of particles is assumed to be the same in all directions, so an isolated object A is struck equally from all sides, resulting in only an inward-directed pressure but no net directional force. With a second object B present, however, a fraction of the particles that would otherwise have struck A from the direction of B is intercepted, so B works as a shield, so-to-speak—that is, from the direction of B, A will be struck by fewer particles than from the opposite direction. Likewise, B will be struck by fewer particles from the direction of A than from the opposite direction. One can say that A and B are "shadowing" each other, and the two bodies are pushed toward each other by the resulting imbalance of forces.

 
P5: Permeability, attenuation and mass proportionality

This shadow obeys the inverse square law, because the imbalance of momentum flow over an entire spherical surface enclosing the object is independent of the size of the enclosing sphere, whereas the surface area of the sphere increases in proportion to the square of the radius. To satisfy the need for mass proportionality, the theory posits that a) the basic elements of matter are very small so that gross matter consists mostly of empty space, and b) that the particles are so small, that only a small fraction of them would be intercepted by gross matter. The result is, that the "shadow" of each body is proportional to the surface of every single element of matter.

Criticism: This theory was declined primarily for thermodynamic reasons because a shadow only appears in this model if the particles or waves are at least partly absorbed, which should lead to an enormous heating of the bodies. Also drag, i.e. the resistance of the particle streams in the direction of motion, is a great problem too. This problem can be solved by assuming superluminal speeds, but this solution largely increases the thermal problems and contradicts special relativity.[2][3]

Vortex Theory

 
Aether vortices around celestial bodies

Because of his philosophical beliefs, René Descartes proposed in 1644 that no empty space can exist and that space must consequently be filled with matter. The parts of this matter tend to move in straight paths, but because they lie close together, they can not move freely, which according to Descartes implies that every motion is circular, so the aether is filled with vortices. Descartes also distinguishes between different forms and sizes of matter in which rough matter resists the circular movement more strongly than fine matter. Due to centrifugal force, matter tends towards the outer edges of the vortex, which causes a condensation of this matter there. The rough matter cannot follow this movement due to its greater inertia—so due to the pressure of the condensed outer matter those parts will be pushed into the center of the vortex. According to Descartes, this inward pressure is nothing other than gravity. He compared this mechanism with the fact that if a rotating, liquid filled vessel is stopped, the liquid goes on to rotate. Now, if one drops small pieces of light matter (e.g. wood) into the vessel, the pieces move to the middle of the vessel.[4][5][6]

Following the basic premises of Descartes, Christiaan Huygens between 1669 and 1690 designed a much more exact vortex model. This model was the first theory of gravitation which was worked out mathematically. He assumed that the aether particles are moving in every direction, but were thrown back at the outer borders of the vortex and this causes (as in the case of Descartes) a greater concentration of fine matter at the outer borders. So also in his model the fine matter presses the rough matter into the center of the vortex. Huygens also found out that the centrifugal force is equal to the force, which acts in the direction of the center of the vortex (centripetal force). He also posited that bodies must consist mostly of empty space so that the aether can penetrate the bodies easily, which is necessary for mass proportionality. He further concluded that the aether moves much faster than the falling bodies. At this time, Newton developed his theory of gravitation which is based on attraction, and although Huygens agreed with the mathematical formalism, he said the model was insufficient due to the lack of a mechanical explanation of the force law. Newton's discovery that gravity obeys the inverse square law surprised Huygens and he tried to take this into account by assuming that the speed of the aether is smaller in greater distance.[6][7][8]

Criticism: Isaac Newton objected to the theory because drag must lead to noticeable deviations of the orbits which were not observed.[9] Another problem was that moons often move in different directions, against the direction of the vortex motion. He devotes most of Book II of the Principia Mathematica to the refutation of Descarteś vortex theory. Also, Huygens' explanation of the inverse square law is circular, because this means that the aether obeys Kepler's third law. But a theory of gravitation has to explain those laws and must not presuppose them.[6][9]

Several British physicists developed vortex atom theory in the late nineteenth century. However, the physicist, William Thomson, 1st Baron Kelvin, developed a quite distinct approach. Whereas Descartes had outlined three species of matter – each linked respectively to the emission, transmission, and reflection of light – Thomson developed a theory based on a unitary continuum.[10]

The Cartesian vortex theory played an important role in the Copernican sun centred theory and in the belief in a cosmos where exist a plurality of stars like the sun, surrounded by multiple planets orbiting around them.[11]

Streams

In a 1675 letter to Henry Oldenburg, and later to Robert Boyle, Newton wrote the following: [Gravity is the result of] “a condensation causing a flow of ether with a corresponding thinning of the ether density associated with the increased velocity of flow.” He also asserted that such a process was consistent with all his other work and Kepler's Laws of Motion.[12] Newton's idea of a pressure drop associated with increased velocity of flow was mathematically formalised as Bernoulli's principle published in Daniel Bernoulli's book Hydrodynamica in 1738.

However, although he later proposed a second explanation (see section below), Newton's comments to that question remained ambiguous. In the third letter to Bentley in 1692 he wrote:[13]

It is inconceivable that inanimate brute matter should, without the mediation of something else which is not material, operate upon and affect other matter, without mutual contact, as it must do if gravitation in the sense of Epicurus be essential and inherent in it. And this is one reason why I desired you would not ascribe 'innate gravity' to me. That gravity should be innate, inherent, and essential to matter, so that one body may act upon another at a distance, through a vacuum, without the mediation of anything else, by and through which their action and force may be conveyed from one to another, is to me so great an absurdity, that I believe no man who has in philosophical matters a competent faculty of thinking can ever fall into it. Gravity must be caused by an agent acting constantly according to certain laws; but whether this agent be material or immaterial, I have left to the consideration of my readers.

On the other hand, Newton is also well known for the phrase Hypotheses non fingo, written in 1713:[14]

I have not as yet been able to discover the reason for these properties of gravity from phenomena, and I do not feign hypotheses. For whatever is not deduced from the phenomena must be called a hypothesis; and hypotheses, whether metaphysical or physical, or based on occult qualities, or mechanical, have no place in experimental philosophy. In this philosophy particular propositions are inferred from the phenomena, and afterwards rendered general by induction.

And according to the testimony of some of his friends, such as Nicolas Fatio de Duillier or David Gregory, Newton thought that gravitation is based directly on divine influence.[8]

Similar to Newton, but mathematically in greater detail, Bernhard Riemann assumed in 1853 that the gravitational aether is an incompressible fluid and normal matter represents sinks in this aether. So if the aether is destroyed or absorbed proportionally to the masses within the bodies, a stream arises and carries all surrounding bodies into the direction of the central mass. Riemann speculated that the absorbed aether is transferred into another world or dimension.[15]

Another attempt to solve the energy problem was made by Ivan Osipovich Yarkovsky in 1888. Based on his aether stream model, which was similar to that of Riemann, he argued that the absorbed aether might be converted into new matter, leading to a mass increase of the celestial bodies.[16]

Criticism: As in the case of Le Sage's theory, the disappearance of energy without explanation violates the energy conservation law. Also some drag must arise, and no process which leads to a creation of matter is known.

Static pressure

Newton updated the second edition of Optics (1717) with another mechanical-ether theory of gravity. Unlike his first explanation (1675 - see Streams), he proposed a stationary aether which gets thinner and thinner nearby the celestial bodies. On the analogy of the lift, a force arises, which pushes all bodies to the central mass. He minimized drag by stating an extremely low density of the gravitational aether.

Like Newton, Leonhard Euler presupposed in 1760 that the gravitational aether loses density in accordance with the inverse square law. Similarly to others, Euler also assumed that to maintain mass proportionality, matter consists mostly of empty space.[17]

Criticism: Both Newton and Euler gave no reason why the density of that static aether should change. Furthermore, James Clerk Maxwell pointed out that in this "hydrostatic" model "the state of stress... which we must suppose to exist in the invisible medium, is 3000 times greater than that which the strongest steel could support".[18]

Waves

Robert Hooke speculated in 1671 that gravitation is the result of all bodies emitting waves in all directions through the aether. Other bodies, which interact with these waves, move in the direction of the source of the waves. Hooke saw an analogy to the fact that small objects on a disturbed surface of water move to the center of the disturbance.[19]

A similar theory was worked out mathematically by James Challis from 1859 to 1876. He calculated that the case of attraction occurs if the wavelength is large in comparison with the distance between the gravitating bodies. If the wavelength is small, the bodies repel each other. By a combination of these effects, he also tried to explain all other forces.[20]

Criticism: Maxwell objected that this theory requires a steady production of waves, which must be accompanied by an infinite consumption of energy.[21] Challis himself admitted, that he hadn't reached a definite result due to the complexity of the processes.[19]

Pulsation

Lord Kelvin (1871) and Carl Anton Bjerknes (1871) assumed that all bodies pulsate in the aether. This was in analogy to the fact that, if the pulsation of two spheres in a fluid is in phase, they will attract each other; and if the pulsation of two spheres is not in phase, they will repel each other. This mechanism was also used for explaining the nature of electric charges. Among others, this hypothesis has also been examined by George Gabriel Stokes and Woldemar Voigt.[22]

Criticism : To explain universal gravitation, one is forced to assume that all pulsations in the universe are in phase—which appears very implausible. In addition, the aether should be incompressible to ensure that attraction also arises at greater distances.[22] And Maxwell argued that this process must be accompanied by a permanent new production and destruction of aether.[18]

Other historical speculations

In 1690, Pierre Varignon assumed that all bodies are exposed to pushes by aether particles from all directions, and that there is some sort of limitation at a certain distance from the Earth's surface which cannot be passed by the particles. He assumed that if a body is closer to the Earth than to the limitation boundary, then the body would experience a greater push from above than from below, causing it to fall toward the Earth.[23]

In 1748, Mikhail Lomonosov assumed that the effect of the aether is proportional to the complete surface of the elementary components of which matter consists (similar to Huygens and Fatio before him). He also assumed an enormous penetrability of the bodies. However, no clear description was given by him as to how exactly the aether interacts with matter so that the law of gravitation arises.[24]

In 1821, John Herapath tried to apply his co-developed model of the kinetic theory of gases on gravitation. He assumed that the aether is heated by the bodies and loses density so that other bodies are pushed to these regions of lower density.[25] However, it was shown by Taylor that the decreased density due to thermal expansion is compensated for by the increased speed of the heated particles; therefore, no attraction arises.[19]

Recent theorizing

These mechanical explanations for gravity never gained widespread acceptance, although such ideas continued to be studied occasionally by physicists until the beginning of the twentieth century, by which time it was generally considered to be conclusively discredited. However, some researchers outside the scientific mainstream still try to work out some consequences of those theories.

Le Sage's theory was studied by Radzievskii and Kagalnikova (1960),[26] Shneiderov (1961),[27] Buonomano and Engels (1976),[28] Adamut (1982),[29] Jaakkola (1996),[30] Tom Van Flandern (1999),[31] and Edwards (2007).[32] A variety of Le Sage models and related topics are discussed in Edwards, et al.[33]

Gravity due to static pressure was recently studied by Arminjon.[34]

References

  1. ^ Taylor (1876), Peck (1903), secondary sources
  2. ^ Poincaré (1908), Secondary sources
  3. ^ Maxwell (1875, Atom), Secondary sources
  4. ^ Descartes, R. (1824–1826), Cousin, V. (ed.), "Les principes de la philosophie (1644)", Oeuvres de Descartes, Paris: F.-G. Levrault, 3
  5. ^ Descartes, 1644; Zehe, 1980, pp. 65–70; Van Lunteren, p. 47
  6. ^ a b c Zehe (1980), Secondary sources
  7. ^ Huygens, C. (1944), Société Hollaise des Sciences (ed.), "Discours de la Cause de la Pesanteur (1690)", Oeuvres Complètes de Christiaan Huygens, Den Haag, 21: 443–488
  8. ^ a b Van Lunteren (2002), Secondary sources
  9. ^ a b Newton, I. (1846), Newton's Principia : the mathematical principles of natural philosophy (1687), New York: Daniel Adee
  10. ^ Kragh, Helge (2002). "The Vortex Atom: A Victorian Theory of Everything". Centaurus. 44 (1–2): 32–114. doi:10.1034/j.1600-0498.2002.440102.x. ISSN 0008-8994. Retrieved 9 March 2019.
  11. ^ "Physical Astronomy for the Mechanistic Universe". Library of Congress. Archived from the original on April 26, 2015. Retrieved May 6, 2021.
  12. ^ I. Newton, letters quoted in detail in The Metaphysical Foundations of Modern Physical Science by Edwin Arthur Burtt, Double day Anchor Books.
  13. ^ http://www.newtonproject.ox.ac.uk/view/texts/normalized/THEM00258 Newton, 1692, 4th letter to Bentley
  14. ^ Isaac Newton (1726). Philosophiae Naturalis Principia Mathematica, General Scholium. Third edition, page 943 of I. Bernard Cohen and Anne Whitman's 1999 translation, University of California Press ISBN 0-520-08817-4, 974 pages.
  15. ^ Riemann, B. (1876), Dedekind, R.; Weber, W. (eds.), "Neue mathematische Prinzipien der Naturphilosophie", Bernhard Riemanns Werke und Gesammelter Nachlass, Leipzig: 528–538
  16. ^ Yarkovsky, I. O. (1888), Hypothese cinetique de la Gravitation universelle et connexion avec la formation des elements chimiques, Moscow
  17. ^ Euler, L. (1776), Briefe an eine deutsche Prinzessin, Nr. 50, 30. August 1760, Leipzig, pp. 173–176, ISBN 9785875783876
  18. ^ a b Maxwell (1875, Attraction), Secondary sources
  19. ^ a b c Taylor (1876), Secondary sources
  20. ^ Challis, J. (1869), Notes of the Principles of Pure and Applied Calculation, Cambridge
  21. ^ Maxwell (1875), Secondary sources
  22. ^ a b Zenneck (1903), Secondary sources
  23. ^ Varignon, P. (1690), Nouvelles conjectures sur la Pesanteur, Paris
  24. ^ Lomonosow, M. (1970), Henry M. Leicester (ed.), "On the Relation of the Amount of Material and Weight (1758)", Mikhail Vasil'evich Lomonosov on the Corpuscular Theory, Cambridge: Harvard University Press: 224–233
  25. ^ Herapath, J. (1821), "On the Causes, Laws and Phenomena of Heat, Gases, Gravitation", Annals of Philosophy, Paris, 9: 273–293
  26. ^ Radzievskii, V.V. & Kagalnikova, I.I. (1960), "The nature of gravitation", Vsesoyuz. Astronom.-Geodezich. Obsch. Byull., 26 (33): 3–14 A rough English translation appeared in a U.S. government technical report: FTD TT64 323; TT 64 11801 (1964), Foreign Tech. Div., Air Force Systems Command, Wright-Patterson AFB, Ohio (reprinted in Pushing Gravity)
  27. ^ Shneiderov, A. J. (1961), "On the internal temperature of the earth", Bollettino di Geofisica Teorica ed Applicata, 3: 137–159
  28. ^ Buonomano, V. & Engel, E. (1976), "Some speculations on a causal unification of relativity, gravitation, and quantum mechanics", Int. J. Theor. Phys., 15 (3): 231–246, Bibcode:1976IJTP...15..231B, doi:10.1007/BF01807095, S2CID 124895055
  29. ^ Adamut, I. A. (1982), "The screen effect of the earth in the TETG. Theory of a screening experiment of a sample body at the equator using the earth as a screen", Nuovo Cimento C, 5 (2): 189–208, Bibcode:1982NCimC...5..189A, doi:10.1007/BF02509010, S2CID 117039637
  30. ^ Jaakkola, T. (1996), "Action-at-a-distance and local action in gravitation: discussion and possible solution of the dilemma" (PDF), Apeiron, 3 (3–4): 61–75
  31. ^ Van Flandern, T. (1999), Dark Matter, Missing Planets and New Comets (2 ed.), Berkeley: North Atlantic Books, pp. Chapters 2–4
  32. ^ Edwards, M .R. (2007), "Photon-Graviton Recycling as Cause of Gravitation" (PDF), Apeiron, 14 (3): 214–233
  33. ^ Edwards, M. R., ed. (2002), Pushing Gravity: New Perspectives on Le Sage's Theory of Gravitation, Montreal: C. Roy Keys Inc.
  34. ^ Mayeul Arminjon (11 November 2004), "Gravity as Archimedes´ Thrust and a Bifurcation in that Theory", Foundations of Physics, 34 (11): 1703–1724, arXiv:physics/0404103, Bibcode:2004FoPh...34.1703A, doi:10.1007/s10701-004-1312-3, S2CID 14421710

Sources

 
Wikisource has several original texts related to Kinetic gravity.
  • Aiton, E.J. (1969), "Newton's Aether-Stream Hypothesis and the Inverse Square Law of Gravitation", Annals of Science, 25 (3): 255–260, doi:10.1080/00033796900200151
  • Carrington, Hereward (1913), Sugden, Sherwood J. B (ed.), "Earlier Theories of Gravity", The Monist, 23 (3): 445–458, doi:10.5840/monist19132332
  • Drude, Paul (1897), "Ueber Fernewirkungen", Annalen der Physik, 298 (12): I–XLIX, Bibcode:1897AnP...298D...1D, doi:10.1002/andp.18972981220
  • Hall, Thomas Proctor (1895), "Physical Theories of Gravitation" , Proceedings of the Iowa Academy of Science, 3: 47–52
  • Helm, Georg (1881), "Ueber die Vermittelung der Fernewirkungen durch den Aether", Annalen der Physik, 250 (9): 149–176, Bibcode:1881AnP...250..149H, doi:10.1002/andp.18812500912
  • Isenkrahe, Caspar (1892), "Über die Rückführung der Schwere auf Absorption und die daraus abgeleiteten Gesetze", Abhandlungen zur Geschichte der Mathematik, vol. 6, Leipzig, pp. 161–204
  • Maxwell, James Clerk (1878), "Atom" , in Baynes, T. S. (ed.), Encyclopædia Britannica, vol. 3 (9th ed.), New York: Charles Scribner's Sons, pp. 36–49
  • Peck, J. W. (1903), "The Corpuscular Theories of Gravitation" , Proceedings of the Royal Philosophical Society of Glasgow, 34: 17–44
  • Poincaré, Henri (1914) [1908], "Lesage's theory" , Science and Method, London, New York: Nelson & Sons, pp. 246–253
  • Preston, Samuel Tolver (1895), "Comparative Review of some Dynamical Theories of Gravitation" , Philosophical Magazine, 5th series, 39 (237): 145–159, doi:10.1080/14786449508620698
  • Taylor, William Bower (1876), "Kinetic Theories of Gravitation" , Smithsonian Report: 205–282
  • Van Lunteren, F. (2002), "Nicolas Fatio de Duillier on the mechanical cause of Gravitation", in Edwards, M.R. (ed.), Pushing Gravity: New Perspectives on Le Sage's Theory of Gravitation, Montreal: C. Roy Keys Inc., pp. 41–59

January 29, 2023
mechanical, explanations, gravitation, kinetic, theories, gravitation, attempts, explain, action, gravity, basic, mechanical, processes, such, pressure, forces, caused, pushes, without, action, distance, these, theories, were, developed, from, 16th, until, 19t. Mechanical explanations of gravitation or kinetic theories of gravitation are attempts to explain the action of gravity by aid of basic mechanical processes such as pressure forces caused by pushes without the use of any action at a distance These theories were developed from the 16th until the 19th century in connection with the aether However such models are no longer regarded as viable theories within the mainstream scientific community and general relativity is now the standard model to describe gravitation without the use of actions at a distance Modern quantum gravity hypotheses also attempt to describe gravity by more fundamental processes such as particle fields but they are not based on classical mechanics Contents 1 Screening 2 Vortex Theory 3 Streams 4 Static pressure 5 Waves 6 Pulsation 7 Other historical speculations 8 Recent theorizing 9 References 10 SourcesScreening EditMain article Le Sage s theory of gravitation This theory is probably 1 the best known mechanical explanation and was developed for the first time by Nicolas Fatio de Duillier in 1690 and re invented among others by Georges Louis Le Sage 1748 Lord Kelvin 1872 and Hendrik Lorentz 1900 and criticized by James Clerk Maxwell 1875 and Henri Poincare 1908 The theory posits that the force of gravity is the result of tiny particles or waves moving at high speed in all directions throughout the universe The intensity of the flux of particles is assumed to be the same in all directions so an isolated object A is struck equally from all sides resulting in only an inward directed pressure but no net directional force With a second object B present however a fraction of the particles that would otherwise have struck A from the direction of B is intercepted so B works as a shield so to speak that is from the direction of B A will be struck by fewer particles than from the opposite direction Likewise B will be struck by fewer particles from the direction of A than from the opposite direction One can say that A and B are shadowing each other and the two bodies are pushed toward each other by the resulting imbalance of forces P5 Permeability attenuation and mass proportionality This shadow obeys the inverse square law because the imbalance of momentum flow over an entire spherical surface enclosing the object is independent of the size of the enclosing sphere whereas the surface area of the sphere increases in proportion to the square of the radius To satisfy the need for mass proportionality the theory posits that a the basic elements of matter are very small so that gross matter consists mostly of empty space and b that the particles are so small that only a small fraction of them would be intercepted by gross matter The result is that the shadow of each body is proportional to the surface of every single element of matter Criticism This theory was declined primarily for thermodynamic reasons because a shadow only appears in this model if the particles or waves are at least partly absorbed which should lead to an enormous heating of the bodies Also drag i e the resistance of the particle streams in the direction of motion is a great problem too This problem can be solved by assuming superluminal speeds but this solution largely increases the thermal problems and contradicts special relativity 2 3 Vortex Theory Edit Aether vortices around celestial bodies Because of his philosophical beliefs Rene Descartes proposed in 1644 that no empty space can exist and that space must consequently be filled with matter The parts of this matter tend to move in straight paths but because they lie close together they can not move freely which according to Descartes implies that every motion is circular so the aether is filled with vortices Descartes also distinguishes between different forms and sizes of matter in which rough matter resists the circular movement more strongly than fine matter Due to centrifugal force matter tends towards the outer edges of the vortex which causes a condensation of this matter there The rough matter cannot follow this movement due to its greater inertia so due to the pressure of the condensed outer matter those parts will be pushed into the center of the vortex According to Descartes this inward pressure is nothing other than gravity He compared this mechanism with the fact that if a rotating liquid filled vessel is stopped the liquid goes on to rotate Now if one drops small pieces of light matter e g wood into the vessel the pieces move to the middle of the vessel 4 5 6 Following the basic premises of Descartes Christiaan Huygens between 1669 and 1690 designed a much more exact vortex model This model was the first theory of gravitation which was worked out mathematically He assumed that the aether particles are moving in every direction but were thrown back at the outer borders of the vortex and this causes as in the case of Descartes a greater concentration of fine matter at the outer borders So also in his model the fine matter presses the rough matter into the center of the vortex Huygens also found out that the centrifugal force is equal to the force which acts in the direction of the center of the vortex centripetal force He also posited that bodies must consist mostly of empty space so that the aether can penetrate the bodies easily which is necessary for mass proportionality He further concluded that the aether moves much faster than the falling bodies At this time Newton developed his theory of gravitation which is based on attraction and although Huygens agreed with the mathematical formalism he said the model was insufficient due to the lack of a mechanical explanation of the force law Newton s discovery that gravity obeys the inverse square law surprised Huygens and he tried to take this into account by assuming that the speed of the aether is smaller in greater distance 6 7 8 Criticism Isaac Newton objected to the theory because drag must lead to noticeable deviations of the orbits which were not observed 9 Another problem was that moons often move in different directions against the direction of the vortex motion He devotes most of Book II of the Principia Mathematica to the refutation of Descartes vortex theory Also Huygens explanation of the inverse square law is circular because this means that the aether obeys Kepler s third law But a theory of gravitation has to explain those laws and must not presuppose them 6 9 Several British physicists developed vortex atom theory in the late nineteenth century However the physicist William Thomson 1st Baron Kelvin developed a quite distinct approach Whereas Descartes had outlined three species of matter each linked respectively to the emission transmission and reflection of light Thomson developed a theory based on a unitary continuum 10 The Cartesian vortex theory played an important role in the Copernican sun centred theory and in the belief in a cosmos where exist a plurality of stars like the sun surrounded by multiple planets orbiting around them 11 Streams EditIn a 1675 letter to Henry Oldenburg and later to Robert Boyle Newton wrote the following Gravity is the result of a condensation causing a flow of ether with a corresponding thinning of the ether density associated with the increased velocity of flow He also asserted that such a process was consistent with all his other work and Kepler s Laws of Motion 12 Newton s idea of a pressure drop associated with increased velocity of flow was mathematically formalised as Bernoulli s principle published in Daniel Bernoulli s book Hydrodynamica in 1738 However although he later proposed a second explanation see section below Newton s comments to that question remained ambiguous In the third letter to Bentley in 1692 he wrote 13 It is inconceivable that inanimate brute matter should without the mediation of something else which is not material operate upon and affect other matter without mutual contact as it must do if gravitation in the sense of Epicurus be essential and inherent in it And this is one reason why I desired you would not ascribe innate gravity to me That gravity should be innate inherent and essential to matter so that one body may act upon another at a distance through a vacuum without the mediation of anything else by and through which their action and force may be conveyed from one to another is to me so great an absurdity that I believe no man who has in philosophical matters a competent faculty of thinking can ever fall into it Gravity must be caused by an agent acting constantly according to certain laws but whether this agent be material or immaterial I have left to the consideration of my readers On the other hand Newton is also well known for the phrase Hypotheses non fingo written in 1713 14 I have not as yet been able to discover the reason for these properties of gravity from phenomena and I do not feign hypotheses For whatever is not deduced from the phenomena must be called a hypothesis and hypotheses whether metaphysical or physical or based on occult qualities or mechanical have no place in experimental philosophy In this philosophy particular propositions are inferred from the phenomena and afterwards rendered general by induction And according to the testimony of some of his friends such as Nicolas Fatio de Duillier or David Gregory Newton thought that gravitation is based directly on divine influence 8 Similar to Newton but mathematically in greater detail Bernhard Riemann assumed in 1853 that the gravitational aether is an incompressible fluid and normal matter represents sinks in this aether So if the aether is destroyed or absorbed proportionally to the masses within the bodies a stream arises and carries all surrounding bodies into the direction of the central mass Riemann speculated that the absorbed aether is transferred into another world or dimension 15 Another attempt to solve the energy problem was made by Ivan Osipovich Yarkovsky in 1888 Based on his aether stream model which was similar to that of Riemann he argued that the absorbed aether might be converted into new matter leading to a mass increase of the celestial bodies 16 Criticism As in the case of Le Sage s theory the disappearance of energy without explanation violates the energy conservation law Also some drag must arise and no process which leads to a creation of matter is known Static pressure EditNewton updated the second edition of Optics 1717 with another mechanical ether theory of gravity Unlike his first explanation 1675 see Streams he proposed a stationary aether which gets thinner and thinner nearby the celestial bodies On the analogy of the lift a force arises which pushes all bodies to the central mass He minimized drag by stating an extremely low density of the gravitational aether Like Newton Leonhard Euler presupposed in 1760 that the gravitational aether loses density in accordance with the inverse square law Similarly to others Euler also assumed that to maintain mass proportionality matter consists mostly of empty space 17 Criticism Both Newton and Euler gave no reason why the density of that static aether should change Furthermore James Clerk Maxwell pointed out that in this hydrostatic model the state of stress which we must suppose to exist in the invisible medium is 3000 times greater than that which the strongest steel could support 18 Waves EditRobert Hooke speculated in 1671 that gravitation is the result of all bodies emitting waves in all directions through the aether Other bodies which interact with these waves move in the direction of the source of the waves Hooke saw an analogy to the fact that small objects on a disturbed surface of water move to the center of the disturbance 19 A similar theory was worked out mathematically by James Challis from 1859 to 1876 He calculated that the case of attraction occurs if the wavelength is large in comparison with the distance between the gravitating bodies If the wavelength is small the bodies repel each other By a combination of these effects he also tried to explain all other forces 20 Criticism Maxwell objected that this theory requires a steady production of waves which must be accompanied by an infinite consumption of energy 21 Challis himself admitted that he hadn t reached a definite result due to the complexity of the processes 19 Pulsation EditLord Kelvin 1871 and Carl Anton Bjerknes 1871 assumed that all bodies pulsate in the aether This was in analogy to the fact that if the pulsation of two spheres in a fluid is in phase they will attract each other and if the pulsation of two spheres is not in phase they will repel each other This mechanism was also used for explaining the nature of electric charges Among others this hypothesis has also been examined by George Gabriel Stokes and Woldemar Voigt 22 Criticism To explain universal gravitation one is forced to assume that all pulsations in the universe are in phase which appears very implausible In addition the aether should be incompressible to ensure that attraction also arises at greater distances 22 And Maxwell argued that this process must be accompanied by a permanent new production and destruction of aether 18 Other historical speculations EditIn 1690 Pierre Varignon assumed that all bodies are exposed to pushes by aether particles from all directions and that there is some sort of limitation at a certain distance from the Earth s surface which cannot be passed by the particles He assumed that if a body is closer to the Earth than to the limitation boundary then the body would experience a greater push from above than from below causing it to fall toward the Earth 23 In 1748 Mikhail Lomonosov assumed that the effect of the aether is proportional to the complete surface of the elementary components of which matter consists similar to Huygens and Fatio before him He also assumed an enormous penetrability of the bodies However no clear description was given by him as to how exactly the aether interacts with matter so that the law of gravitation arises 24 In 1821 John Herapath tried to apply his co developed model of the kinetic theory of gases on gravitation He assumed that the aether is heated by the bodies and loses density so that other bodies are pushed to these regions of lower density 25 However it was shown by Taylor that the decreased density due to thermal expansion is compensated for by the increased speed of the heated particles therefore no attraction arises 19 Recent theorizing EditThese mechanical explanations for gravity never gained widespread acceptance although such ideas continued to be studied occasionally by physicists until the beginning of the twentieth century by which time it was generally considered to be conclusively discredited However some researchers outside the scientific mainstream still try to work out some consequences of those theories Le Sage s theory was studied by Radzievskii and Kagalnikova 1960 26 Shneiderov 1961 27 Buonomano and Engels 1976 28 Adamut 1982 29 Jaakkola 1996 30 Tom Van Flandern 1999 31 and Edwards 2007 32 A variety of Le Sage models and related topics are discussed in Edwards et al 33 Gravity due to static pressure was recently studied by Arminjon 34 References Edit Taylor 1876 Peck 1903 secondary sources Poincare 1908 Secondary sources Maxwell 1875 Atom Secondary sources Descartes R 1824 1826 Cousin V ed Les principes de la philosophie 1644 Oeuvres de Descartes Paris F G Levrault 3 Descartes 1644 Zehe 1980 pp 65 70 Van Lunteren p 47 a b c Zehe 1980 Secondary sources Huygens C 1944 Societe Hollaise des Sciences ed Discours de la Cause de la Pesanteur 1690 Oeuvres Completes de Christiaan Huygens Den Haag 21 443 488 a b Van Lunteren 2002 Secondary sources a b Newton I 1846 Newton s Principia the mathematical principles of natural philosophy 1687 New York Daniel Adee Kragh Helge 2002 The Vortex Atom A Victorian Theory of Everything Centaurus 44 1 2 32 114 doi 10 1034 j 1600 0498 2002 440102 x ISSN 0008 8994 Retrieved 9 March 2019 Physical Astronomy for the Mechanistic Universe Library of Congress Archived from the original on April 26 2015 Retrieved May 6 2021 I Newton letters quoted in detail in The Metaphysical Foundations of Modern Physical Science by Edwin Arthur Burtt Double day Anchor Books http www newtonproject ox ac uk view texts normalized THEM00258 Newton 1692 4th letter to Bentley Isaac Newton 1726 Philosophiae Naturalis Principia Mathematica General Scholium Third edition page 943 of I Bernard Cohen and Anne Whitman s 1999 translation University of California Press ISBN 0 520 08817 4 974 pages Riemann B 1876 Dedekind R Weber W eds Neue mathematische Prinzipien der Naturphilosophie Bernhard Riemanns Werke und Gesammelter Nachlass Leipzig 528 538 Yarkovsky I O 1888 Hypothese cinetique de la Gravitation universelle et connexion avec la formation des elements chimiques Moscow Euler L 1776 Briefe an eine deutsche Prinzessin Nr 50 30 August 1760 Leipzig pp 173 176 ISBN 9785875783876 a b Maxwell 1875 Attraction Secondary sources a b c Taylor 1876 Secondary sources Challis J 1869 Notes of the Principles of Pure and Applied Calculation Cambridge Maxwell 1875 Secondary sources a b Zenneck 1903 Secondary sources Varignon P 1690 Nouvelles conjectures sur la Pesanteur Paris Lomonosow M 1970 Henry M Leicester ed On the Relation of the Amount of Material and Weight 1758 Mikhail Vasil evich Lomonosov on the Corpuscular Theory Cambridge Harvard University Press 224 233 Herapath J 1821 On the Causes Laws and Phenomena of Heat Gases Gravitation Annals of Philosophy Paris 9 273 293 Radzievskii V V amp Kagalnikova I I 1960 The nature of gravitation Vsesoyuz Astronom Geodezich Obsch Byull 26 33 3 14 A rough English translation appeared in a U S government technical report FTD TT64 323 TT 64 11801 1964 Foreign Tech Div Air Force Systems Command Wright Patterson AFB Ohio reprinted in Pushing Gravity Shneiderov A J 1961 On the internal temperature of the earth Bollettino di Geofisica Teorica ed Applicata 3 137 159 Buonomano V amp Engel E 1976 Some speculations on a causal unification of relativity gravitation and quantum mechanics Int J Theor Phys 15 3 231 246 Bibcode 1976IJTP 15 231B doi 10 1007 BF01807095 S2CID 124895055 Adamut I A 1982 The screen effect of the earth in the TETG Theory of a screening experiment of a sample body at the equator using the earth as a screen Nuovo Cimento C 5 2 189 208 Bibcode 1982NCimC 5 189A doi 10 1007 BF02509010 S2CID 117039637 Jaakkola T 1996 Action at a distance and local action in gravitation discussion and possible solution of the dilemma PDF Apeiron 3 3 4 61 75 Van Flandern T 1999 Dark Matter Missing Planets and New Comets 2 ed Berkeley North Atlantic Books pp Chapters 2 4 Edwards M R 2007 Photon Graviton Recycling as Cause of Gravitation PDF Apeiron 14 3 214 233 Edwards M R ed 2002 Pushing Gravity New Perspectives on Le Sage s Theory of Gravitation Montreal C Roy Keys Inc Mayeul Arminjon 11 November 2004 Gravity as Archimedes Thrust and a Bifurcation in that Theory Foundations of Physics 34 11 1703 1724 arXiv physics 0404103 Bibcode 2004FoPh 34 1703A doi 10 1007 s10701 004 1312 3 S2CID 14421710Sources Edit Wikisource has several original texts related to Kinetic gravity Aiton E J 1969 Newton s Aether Stream Hypothesis and the Inverse Square Law of Gravitation Annals of Science 25 3 255 260 doi 10 1080 00033796900200151Carrington Hereward 1913 Sugden Sherwood J B ed Earlier Theories of Gravity The Monist 23 3 445 458 doi 10 5840 monist19132332Drude Paul 1897 Ueber Fernewirkungen Annalen der Physik 298 12 I XLIX Bibcode 1897AnP 298D 1D doi 10 1002 andp 18972981220Hall Thomas Proctor 1895 Physical Theories of Gravitation Proceedings of the Iowa Academy of Science 3 47 52Helm Georg 1881 Ueber die Vermittelung der Fernewirkungen durch den Aether Annalen der Physik 250 9 149 176 Bibcode 1881AnP 250 149H doi 10 1002 andp 18812500912Isenkrahe Caspar 1892 Uber die Ruckfuhrung der Schwere auf Absorption und die daraus abgeleiteten Gesetze Abhandlungen zur Geschichte der Mathematik vol 6 Leipzig pp 161 204Maxwell James Clerk 1878 Atom in Baynes T S ed Encyclopaedia Britannica vol 3 9th ed New York Charles Scribner s Sons pp 36 49Maxwell James Clerk 1878 Attraction in Baynes T S ed Encyclopaedia Britannica vol 3 9th ed New York Charles Scribner s Sons pp 63 65Peck J W 1903 The Corpuscular Theories of Gravitation Proceedings of the Royal Philosophical Society of Glasgow 34 17 44Poincare Henri 1914 1908 Lesage s theory Science and Method London New York Nelson amp Sons pp 246 253Preston Samuel Tolver 1895 Comparative Review of some Dynamical Theories of Gravitation Philosophical Magazine 5th series 39 237 145 159 doi 10 1080 14786449508620698Taylor William Bower 1876 Kinetic Theories of Gravitation Smithsonian Report 205 282Van Lunteren F 2002 Nicolas Fatio de Duillier on the mechanical cause of Gravitation in Edwards M R ed Pushing Gravity New Perspectives on Le Sage s Theory of Gravitation Montreal C Roy Keys Inc pp 41 59Zehe Horst 1980 Die Gravitationstheorie des Nicolas Fatio de Duillier Archive for History of Exact Sciences Hildesheim Gerstenberg 28 1 1 23 Bibcode 1983AHES 28 1Z doi 10 1007 BF00327787 ISBN 3 8067 0862 2 S2CID 123509380Zenneck Jonathan 1903 Gravitation Encyklopadie der Mathematischen Wissenschaften mit Einschluss Ihrer Anwendungen 5 1 25 67 doi 10 1007 978 3 663 16016 8 2 ISBN 978 3 663 15445 7 permanent dead link Retrieved from https en wikipedia org w index php title Mechanical explanations of gravitation amp oldid 1110418614, wikipedia, wiki, book, books, library,

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