- Aristotelian physics
The Greek
philosopher Aristotle (384 BC –322 BC ) developed many theories on the nature ofphysics that are completely different from what are now understood as thelaws of physics . These involved what Aristotle described as the four elements, as well as a variety of principles, most of which modern science has now disproved, and which provide no significant roots to any area of modern physics.He spoke intimately of the relation between these elements, of their dynamics, and how they impacted on the earth, and were, in many cases, attracted to each other by unspecified forces. He also taught miscellaneous other aspects of his physics model, including his widely believed theory relating to moving energy.
Aristotelian physics
Aristotle taught that the elements that composed the
Earth were different from those that made up the heavens andOuter space .Cite web|url=http://csep10.phys.utk.edu/astr161/lect/history/aristotle_dynamics.html|title=Physics of Aristotel vs. The Physics of Galileo|accessmonthday=26 March|accessyear=2007] He also taught thatdynamics were mostly determined by the characteristics and nature of thesubstance s that the object that was moving was composed of.Elements
Aristotle believed that there were four main elements or
compounds that made up theEarth : earth, air, water and fire.Ref_label|A|a|noneCite web|url=http://www.hep.fsu.edu/~wahl/Quarknet/pepperlect/aristogalnewt.pdf|title=www.hep.fsu.edu|accessmonthday=26 March|accessyear=2007] He also held that all the heavens, and every particle ofmatter in theuniverse , was formed out of another, fifth element he called 'aether ' (also transliterated as "ether"), which was supposedly weightless and "incorruptible". Aether was also known by the name 'quintessence' - literally, "fifth substance".Cite web|url=http://aether.lbl.gov/www/classes/p10/aristotle-physics.html|title=Aristotel's physics|accessmonthday=27 March|accessyear=2007]Heavy substances such as
iron and metals were considered to be primarily consisting of the "element" of earth, with a limited amount ofmatter from the other elements. Other, less heavy and/or dense objects were thought to be less earthy, and composed of a greater mixture of the other elements.Human s were shaped with all of the substances, with the exception of ether, but the relative proportion of elements was unique to each person, and there was no standard amount of each within the human body.Dynamics
Aristotle held that each of the four worldly elements would each seek each other and cluster together, and that this seeking of other similar elements would have to be hindered to be stopped, as it was as natural as two
magnet s rejecting each other, or rain falling from the clouds. For instance, becausesmoke was mainly air, it would rise to meet the air in the sky. He also taught that objects and matter could only move so long as a form ofenergy was forcing it in a given direction.Cite web|url=http://csep10.phys.utk.edu/astr161/lect/history/aristotle_dynamics.html|title=Physics of Aristotle vs. The Physics of Galileo|accessmonthday=28 March|accessyear=2007] Therefore, if all the applied forces on Earth were removed, such as the throwing of a rock, then nothing could move.Cite web|url=http://csep10.phys.utk.edu/astr161/lect/history/aristotle_dynamics.html|title=Physics of Aristotle vs. The Physics of Galileo|accessmonthday=28 March|accessyear=2007] This idea had flaws that were visible even at the time the concept was formulated. Many people questioned how an object such as anarrow could continue to move forward after it had left the power released by the string, and continue to sail forward. Aristotle proposed an idea that arrows, etc., created a type ofvacuum behind them that forced them forward., which was consistent with his interpretation of motion as an interaction of the moving object and the medium through which it moves. Since the turbulent motion of air around an arrow is very complicated, and still not fully understood, any discrepancy with observation could be swept under the rug.Because Aristotle placed the medium at the center of his theory of motion, he could not make sense of the notion of a void central to the atomic theory of
Democritus . A void is a place free of anything, and since Aristotle asserted that motion required a medium, he came to the conclusion that a void was an incomprehensible idea. Aristotle's believed that the motion of an object is inversely proportional to the density of the medium. the more tenuous a medium is, the faster the motion. If an object is moving in void, Aristotle believed that it would be moving infinitely fast, so that matter would instantly fill up any void at the moment it formed. [Land, Helen "The Order of Nature in Aristotle's Physics: Place and the Elements" (1998)]Gravity
The Aristotelian theory of gravity was a theory that stated that all bodies move towards their natural place. For some objects,
Aristotle claimed the natural place to be the center of theearth , wherefore they fall towards it. For other objects, the natural place is the heavenly spheres, wherefore gases, steam for example, move away from the centre of the earth and towards heaven and to themoon . Thespeed of this motion was thought to be proportional to themass of the object.Medieval criticisms
During the
Middle Ages , the Aristotelian theory of gravity was first criticized and/or modified byJohn Philoponus and later by Muslim physicists.Ja'far Muhammad ibn Mūsā ibn Shākir (800-873) of theBanū Mūsā wrote the "Astral Motion" and "The Force of Attraction", where he discovered that there was aforce of attraction between heavenly bodies, [K. A. Waheed (1978). "Islam and The Origins of Modern Science", p. 27. Islamic Publication Ltd., Lahore.] foreshadowingNewton's law of universal gravitation . [Robert Briffault (1938). "The Making of Humanity", p. 191.]Ibn al-Haytham (965-1039) also discussed the theory of attraction betweenmass es, and it seems that he was aware of the magnitude ofacceleration due togravity and he discovered that the heavenly bodies "were accountable to the laws of physics". [Duhem, Pierre (1908, 1969). "To Save the Phenomena: An Essay on the Idea of Physical theory from Plato to Galileo", p. 28. University of Chicago Press, Chicago.]Abū Rayhān al-Bīrūnī (973-1048) was the first to realize thatacceleration is connected with non-uniform motion, part ofNewton's second law of motion .MacTutor|id=Al-Biruni|title=Al-Biruni] During his debate withAvicenna , al-Biruni also criticized the Aristotelian theory of gravity for denying the existence of or gravity in thecelestial sphere s and for its notion ofcircular motion being an innate property of the heavenly bodies.Rafik Berjak and Muzaffar Iqbal, "Ibn Sina--Al-Biruni correspondence", "Islam & Science", June 2003.]In 1121,
al-Khazini , in "The Book of the Balance of Wisdom", proposed that the gravity andgravitational potential energy of a body varies depending on its distance from the centre of the Earth. [Mariam Rozhanskaya and I. S. Levinova (1996), "Statics", in Roshdi Rashed, ed., "Encyclopedia of the History of Arabic Science ", Vol. 2, p. 614-642 [621-622] .Routledge , London and New York.]Hibat Allah Abu'l-Barakat al-Baghdaadi (1080-1165) wrote a critique of Aristotelian physics entitled "al-Mu'tabar", where he negated Aristotle's idea that a constantforce produces uniform motion, as he realized that a force applied continuously producesacceleration , a fundamental law ofclassical mechanics and an early foreshadowing ofNewton's second law of motion . [cite encyclopedia
last =Shlomo Pines
title = Abu'l-Barakāt al-Baghdādī , Hibat Allah
encyclopedia =Dictionary of Scientific Biography
volume = 1
pages = 26-28
publisher = Charles Scribner's Sons
location = New York
date = 1970
isbn = 0684101149
(cf. Abel B. Franco (October 2003). "Avempace, Projectile Motion, and Impetus Theory", "Journal of the History of Ideas" 64 (4), p. 521-546 [528] .)] Like Newton, he described acceleration as the rate of change ofvelocity . [A. C. Crombie, "Augustine to Galileo 2", p. 67.]In the 14th century,
Jean Buridan developed thetheory of impetus , based onAvicenna 's theory of "mayl" and the work ofJohn Philoponus , as an alternative to the Aristotelian theory of motion. The theory of impetus was a precursor to the concepts ofinertia andmomentum in classical mechanics.In the 16th century,
al-Birjandi discussed the possibility of theEarth's rotation . In his analysis of what might occur if the Earth were rotating, he developed a hypothesis similar toGalileo Galilei 's notion of "circularinertia ", [Harv|Ragep|2001b|pp=63-4] which he described in the following observational test:Life and death of Aristotelian physics
The reign of Aristotelian notions of physics lasted for almost two millennia, and provide the earliest known speculative theories of physics. After the work of Alhacen,
Avicenna , Avempace, al-Baghdadi,Jean Buridan ,Galileo ,Descartes ,Isaac Newton , and many others, it became generally accepted that Aristotelian physics were not correct or viable.Cite web|url=http://aether.lbl.gov/www/classes/p10/aristotle-physics.html|title=Aristotel's physics|accessmonthday=28 March|accessyear=2007] Despite this, Aristotle's physics were able to live into the lateseventeenth century , and perhaps longer, as they were still taught in universities at the time. Aristotle's model of physics was the main academic impediment for the creation of the science of physics long after Aristotle's death.In
Europe ,Aristotle 's theory was first convincingly discredited by the work ofGalileo Galilei . Using atelescope , Galileo observed that the moon was not entirely smooth, but had craters and mountains, contradicting the Aristotelian idea of an incorruptible perfectly smooth moon. Galileo also criticized this notion theoretically – a perfectly smooth moon would reflect light unevenly like a shiny billiard ball, so that the edges of the moon's disk would have a different brightness than the point where a tangent plane reflects sunlight directly to the eye. A rough moon reflects in all directions equally, leading to a disk of approximately equal brightness which is what is observed [ Galileo Galilei "Dialog On the Two Principle Systems of the World"] . Galileo also observed thatJupiter has moons, objects which revolve around a body other than the Earth. He noted thephases of Venus, convincingly demonstrating that Venus, and by implication Mercury, travels around the sun, not the Earth.According to legend, Galileo dropped balls of various densities from the Tower of Pisa and found that lighter and heavier ones fell at almost the same speed. In fact, he did quantitative experiments with balls rolling down an inclined plane, a form of falling that is slow enough to be measured without advanced instruments.
Since Aristotle did not believe that motion could be described without a surrounding medium, he couldn't treat
air resistance as a complicating factor. A heavier body falls faster than a lighter one of the same shape in a dense medium like water, and this led Aristotle to speculate that the rate of falling is proportional to the mass and inversely proportional to the density of the medium. From his experience with objects falling in water, he concluded that water is approximately ten times denser than air. By weighing a volume of compressed air, Galileo showed that this overestimates the density of air by a factor of forty [ Galileo Galilei "Two New Sciences"] . From his experiments with inclined planes, he concluded that all bodies fall at the same rate neglecting friction.Galileo also advanced a theoretical argument to support his conclusion. He asked if two bodies of different masses and different rates of fall are tied by a string, does the combined system fall faster because it is now more massive, or does the lighter body in its slower fall hold back the heavier body? The only convincing answer is neither: all the systems fall at the same rate [ Galileo "Dialog Concerning the Two Principal Systems of the World"] .
Followers of Aristotle were aware that the motion of falling bodies was not uniform, but picked up speed with time. Since time is an abstract quantity, the
peripatetic s postulated that the speed was proportional to the distance. Galileo established experimentally that the speed is proportional to the time, but he also gave a theoretical argument that the speed could not possibly be proportional to the distance. In modern terms, if the rate of fall is proportional to the distance, the differential equation for the distance y travelled after time t is:with the condition that . Galileo demonstrated that this system would stay at for all time. If a perturbation set the system into motion somehow, the object would pick up speed exponentially in time, not quadratically [ Galileo "Two New Sciences"] .On the surface of the
moon ,David Scott famously repeated Galileo's experiment by dropping a feather and a hammer from each hand at the same time. In the absence of a substantialatmosphere , the two objects fell and hit the moon's surface at the same time.With his law of universal gravitation
Isaac Newton was the first to mathematically codify a correct theory of gravity. In this theory, any mass is attracted to any other mass by a force which decreases as the inverse square of their distance. In 1915, Newton's theory was modified, but not invalidated, byAlbert Einstein , who developed a new picture ofgravitation , in the framework of his general theory of relativity. See "gravity " for a much more detailed complete discussion.See also
*
Physics (Aristotle) Notes
a Note_label|A|a|none The term 'earth' refers to a pure element that Aristotle theorized, not the actual planet Earth, which is known to be composed of a large number of elements. The same applies to the other terminologies used. 'Air' refers to a pure element of air, opposed to the air that is found in the Earth's atmosphere, which is, again, made up of many elements.
Notes
References
*Harvard reference
last=Ragep
first=F. Jamil
year=2001a
title=Tusi and Copernicus: The Earth's Motion in Context
journal=Science in Context
volume=14
issue=1-2
pages=145–163
publisher=Cambridge University Press
*Harvard reference
last=Ragep
first=F. Jamil
year=2001b
title=Freeing Astronomy from Philosophy: An Aspect of Islamic Influence on Science
journal=Osiris, 2nd Series
volume=16
issue=Science in Theistic Contexts: Cognitive Dimensions
pages=49-64 & 66-71
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