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Inertia

February 15, 2024

This article is about inertia in physics. For other uses, see Inertia (disambiguation).

Inertia is the tendency of objects in motion to stay in motion, and objects at rest to stay at rest, unless a force causes its speed or direction to change. It is one of the fundamental principles in classical physics, and described by Isaac Newton in his first law of motion (also known as The Principle of Inertia).[1] It is one of the primary manifestations of mass, one of the core quantitative properties of physical systems.[2] Newton writes:[3][4]

LAW I. Every object perseveres in its state of rest, or of uniform motion in a right line, except insofar as it is compelled to change that state by forces impressed thereon.

— Isaac Newton, Principa, Translation by Cohen and Whitman, 1999

In his 1687 work Philosophiæ Naturalis Principia Mathematica, Newton defined inertia as a force:

DEFINITION III. The vis insita, or innate force of matter, is a power of resisting by which every body, as much as in it lies, endeavours to persevere in its present state, whether it be of rest or of moving uniformly forward in a right line.[5]

History and development edit

Early understanding of inertial motion edit

Professor John H. Lienhard points out the Mozi – based on a Chinese text from the Warring States period (475–221 BCE) – as having given the first description of inertia.[6] Before the European Renaissance, the prevailing theory of motion in western philosophy was that of Aristotle (384–322 BCE). On the surface of the Earth, the inertia property of physical objects is often masked by gravity and the effects of friction and air resistance, both of which tend to decrease the speed of moving objects (commonly to the point of rest). This misled the philosopher Aristotle to believe that objects would move only as long as force was applied to them.[7][8] Aristotle said that all moving objects (on Earth) eventually come to rest unless an external power (force) continued to move them.[9] Aristotle explained the continued motion of projectiles, after being separated from their projector, as an (itself unexplained) action of the surrounding medium continuing to move the projectile.[10]

Despite its general acceptance, Aristotle's concept of motion[11] was disputed on several occasions by notable philosophers over nearly two millennia. For example, Lucretius (following, presumably, Epicurus) stated that the "default state" of the matter was motion, not stasis (stagnation).[12] In the 6th century, John Philoponus criticized the inconsistency between Aristotle's discussion of projectiles, where the medium keeps projectiles going, and his discussion of the void, where the medium would hinder a body's motion. Philoponus proposed that motion was not maintained by the action of a surrounding medium, but by some property imparted to the object when it was set in motion. Although this was not the modern concept of inertia, for there was still the need for a power to keep a body in motion, it proved a fundamental step in that direction.[13][14] This view was strongly opposed by Averroes and by many scholastic philosophers who supported Aristotle. However, this view did not go unchallenged in the Islamic world, where Philoponus had several supporters who further developed his ideas.

In the 11th century, Persian polymath Ibn Sina (Avicenna) claimed that a projectile in a vacuum would not stop unless acted upon.[15]

Theory of impetus edit

Main article: Theory of impetus
See also: Conatus

In the 14th century, Jean Buridan rejected the notion that a motion-generating property, which he named impetus, dissipated spontaneously. Buridan's position was that a moving object would be arrested by the resistance of the air and the weight of the body which would oppose its impetus.[16] Buridan also maintained that impetus increased with speed; thus, his initial idea of impetus was similar in many ways to the modern concept of momentum. Despite the obvious similarities to more modern ideas of inertia, Buridan saw his theory as only a modification to Aristotle's basic philosophy, maintaining many other peripatetic views, including the belief that there was still a fundamental difference between an object in motion and an object at rest. Buridan also believed that impetus could be not only linear but also circular in nature, causing objects (such as celestial bodies) to move in a circle. Buridan's theory was followed up by his pupil Albert of Saxony (1316–1390) and the Oxford Calculators, who performed various experiments which further undermined the Aristotelian model. Their work in turn was elaborated by Nicole Oresme who pioneered the practice of illustrating the laws of motion with graphs.

Shortly before Galileo's theory of inertia, Giambattista Benedetti modified the growing theory of impetus to involve linear motion alone:

[Any] portion of corporeal matter which moves by itself when an impetus has been impressed on it by any external motive force has a natural tendency to move on a rectilinear, not a curved, path.[17]

Benedetti cites the motion of a rock in a sling as an example of the inherent linear motion of objects, forced into circular motion.

Classical inertia edit

According to Charles Coulston Gillispie, inertia "entered science as a physical consequence of Descartes' geometrization of space-matter, combined with the immutability of God."[18] The first physicist to completely break away from the Aristotelian model of motion was Isaac Beeckman in 1614.[19] The term "inertia" was first introduced by Johannes Kepler in his Epitome Astronomiae Copernicanae[20] (published in three parts from 1617 to 1621); however, the meaning of Kepler's term (which he derived from the Latin word for "idleness" or "laziness") was not quite the same as its modern interpretation. Kepler defined inertia only in terms of resistance to movement, once again based on the presumption that rest was a natural state which did not need explanation. It was not until the later work of Galileo and Newton unified rest and motion in one principle that the term "inertia" could be applied to these concepts as it is today.[21]

The principle of inertia, as formulated by Aristotle for "motions in a void",[22] includes that a mundane object tends to resist a change in motion. The Aristotelian division of motion into mundane and celestial became increasingly problematic in the face of the conclusions of Nicolaus Copernicus in the 16th century, who argued that the Earth is never at rest, but is actually in constant motion around the Sun.[23]

 
Isaac Newton, 1689
 
Galileo Galilei

Galileo, in his further development of the Copernican model, recognized these problems with the then-accepted nature of motion and, at least partially, as a result, included a restatement of Aristotle's description of motion in a void as a basic physical principle:

A body moving on a level surface will continue in the same direction at a constant speed unless disturbed.

Galileo writes that "all external impediments removed, a heavy body on a spherical surface concentric with the earth will maintain itself in that state in which it has been; if placed in a movement towards the west (for example), it will maintain itself in that movement."[24] This notion, which is termed "circular inertia" or "horizontal circular inertia" by historians of science, is a precursor to but is distinct from Newton's notion of rectilinear inertia.[25][26] For Galileo, a motion is "horizontal" if it does not carry the moving body towards or away from the center of the Earth, and for him, "a ship, for instance, having once received some impetus through the tranquil sea, would move continually around our globe without ever stopping."[27][28] It is also worth noting that Galileo later (in 1632) concluded that based on this initial premise of inertia, it is impossible to tell the difference between a moving object and a stationary one without some outside reference to compare it against.[29] This observation ultimately came to be the basis for Albert Einstein to develop the theory of special relativity.

Concepts of inertia in Galileo's writings would later come to be refined, modified, and codified by Isaac Newton as the first of his Laws of Motion (first published in Newton's work, Philosophiæ Naturalis Principia Mathematica, in 1687):

Every body perseveres in its state of rest, or of uniform motion in a right line, unless it is compelled to change that state by forces impressed thereon.[30]

Despite having defined the concept in his laws of motion, Newton did not actually use the term "inertia.” In fact, originally he viewed the respective phenomenon as being caused by "innate forces" inherent in matter, which resisted any acceleration. Given this perspective, and borrowing from Kepler, Newton attributed the term "inertia" to mean "the innate force possessed by an object which resists changes in motion"; thus, Newton defined "inertia" to mean the cause of the phenomenon, rather than the phenomenon itself. However, Newton's original ideas of "innate resistive force" were ultimately problematic for a variety of reasons, and thus most physicists no longer think in these terms. As no alternate mechanism has been readily accepted, and it is now generally accepted that there may not be one that we can know, the term "inertia" has come to mean simply the phenomenon itself, rather than any inherent mechanism. Thus, ultimately, "inertia" in modern classical physics has come to be a name for the same phenomenon as described by Newton's First Law of Motion, and the two concepts are now considered to be equivalent.

 
The effect of inertial mass: if pulled slowly, the upper thread breaks (a). If pulled quickly, the lower thread breaks (b).

Relativity edit

Albert Einstein's theory of special relativity, as proposed in his 1905 paper entitled "On the Electrodynamics of Moving Bodies", was built on the understanding of inertial reference frames developed by Galileo, Huygens and Newton. While this revolutionary theory did significantly change the meaning of many Newtonian concepts such as mass, energy, and distance, Einstein's concept of inertia remained at first unchanged from Newton's original meaning. However, this resulted in a limitation inherent in special relativity: the principle of relativity could only apply to inertial reference frames. To address this limitation, Einstein developed his general theory of relativity ("The Foundation of the General Theory of Relativity", 1916), which provided a theory including noninertial (accelerated) reference frames.[31]

In general relativity, the concept of inertial motion got a broader meaning. Taking into account general relativity, inertial motion is any movement of a body that is not affected by forces of electrical, magnetic, or other origin, but that is only under the influence of gravitational masses.[32][33] Physically speaking, this happens to be exactly what a properly functioning three-axis accelerometer is indicating when it does not detect any proper acceleration.

Etymology edit

The term inertia comes from the Latin word iners, meaning idle or sluggish.[34]

Rotational inertia edit

A quantity related to inertia is rotational inertia (→ moment of inertia), the property that a rotating rigid body maintains its state of uniform rotational motion. Its angular momentum remains unchanged unless an external torque is applied; this is called conservation of angular momentum. Rotational inertia is often considered in relation to a rigid body. For example, a gyroscope uses the property that it resists any change in the axis of rotation.

See also edit

References edit

  1. ^ Britannica, Dictionary. "definition of INERTIA". Retrieved 2022-07-08.
  2. ^ Britannica, Science. "inertia physics". Retrieved 2022-07-08.
  3. ^ Andrew Motte's English translation: Newton, Isaac (1846), Newton's Principia: the mathematical principles of natural philosophy (3rd edition), New York: Daniel Adee, p. 83
  4. ^ "What Newton really meant | Daniel Hoek". IAI TV - Changing how the world thinks. 2023-08-17. Retrieved 2023-09-29.
  5. ^ Andrew Motte's English translation: Newton, Isaac (1846), Newton's Principia: the mathematical principles of natural philosophy (3rd edition), New York: Daniel Adee, p. 73
  6. ^ "No. 2080 The Survival of Invention". www.uh.edu.
  7. ^ Aristotle: Minor works (1936), Mechanical Problems (Mechanica), University of Chicago Library: Loeb Classical Library Cambridge (Mass.) and London, p. 407, ...it [a body] stops when the force which is pushing the travelling object has no longer power to push it along...
  8. ^ Pages 2 to 4, Section 1.1, "Skating", Chapter 1, "Things that Move", Louis Bloomfield, Professor of Physics at the University of Virginia, How Everything Works: Making Physics Out of the Ordinary, John Wiley & Sons (2007), hardcover, ISBN 978-0-471-74817-5
  9. ^ Byrne, Christopher (2018). Aristotle's Science of Matter and Motion. University of Toronto Press. p. 21. ISBN 978-1-4875-0396-3. Extract of page 21
  10. ^ Aristotle, Physics, 8.10, 267a1–21; Aristotle, Physics, trans. by R. P. Hardie and R. K. Gaye, 'projectile' 2007-01-29 at the Wayback Machine.
  11. ^ Darling, David (2006). Gravity's arc: the story of gravity, from Aristotle to Einstein and beyond. John Wiley and Sons. pp. 17, 50. ISBN 978-0-471-71989-2.
  12. ^ Lucretius, On the Nature of Things (London: Penguin, 1988), pp. 80–85, 'all must move'
  13. ^ Sorabji, Richard (1988). Matter, space and motion : theories in antiquity and their sequel (1st ed.). Ithaca, N.Y.: Cornell University Press. pp. 227–228. ISBN 978-0801421945.
  14. ^ "John Philoponus". Stanford Encyclopedia of Philosophy. 8 June 2007. Retrieved 26 July 2012.
  15. ^ Espinoza, Fernando. "An Analysis of the Historical Development of Ideas About Motion and its Implications for Teaching". Physics Education. Vol. 40(2). Medieval thought.
  16. ^ Jean Buridan: Quaestiones on Aristotle's Physics (quoted at )
  17. ^ Stillman Drake. Essays on Galileo etc. Vol 3. p. 285.
  18. ^ Gillispie, Charles Coulston (1960). The Edge of Objectivity: An Essay in the History of Scientific Ideas. Princeton University Press. pp. 367–68. ISBN 0-691-02350-6.
  19. ^ van Berkel, Klaas (2013), Isaac Beeckman on Matter and Motion: Mechanical Philosophy in the Making, Johns Hopkins University Press, pp. 105–110, ISBN 9781421409368
  20. ^ Lawrence Nolan (ed.), The Cambridge Descartes Lexicon, Cambridge University Press, 2016, "Inertia.", p. 405
  21. ^ Biad, Abder-Rahim (2018-01-26). Restoring the Bioelectrical Machine. Lulu Press, Inc. ISBN 9781365447709.
  22. ^ 7th paragraph of section 8, book 4 of Physica
  23. ^ Nicholas Copernicus, The Revolutions of the Heavenly Spheres, 1543
  24. ^ Drake, Stillman. "Galilei's presentation of his principle of inertia, p. 113". Retrieved 2022-07-31.
  25. ^ See Alan Chalmers article "Galilean Relativity and Galileo's Relativity", in Correspondence, Invariance and Heuristics: Essays in Honour of Heinz Post, eds. Steven French and Harmke Kamminga, Kluwer Academic Publishers, Dordrecht, 1991, pp. 199–200, ISBN 0792320859. Chalmers does not, however, believe that Galileo's physics had a general principle of inertia, circular or otherwise. page 199
  26. ^ Dijksterhuis E.J. The Mechanisation of the World Picture, Oxford University Press, Oxford, 1961, p. 352
  27. ^ Drake, Stillman. "Discoveries and Opinions of Galileo, p. 113-114". Retrieved 2022-07-31.
  28. ^ According to Newtonian mechanics, if a projectile on a smooth spherical planet is given an initial horizontal velocity, it will not remain on the surface of the planet. Various curves are possible depending on the initial speed and the height of the launch. See Harris Benson University Physics, New York 1991, page 268. If constrained to remain on the surface, by being sandwiched, say, in between two concentric spheres, it will follow a great circle on the surface of the earth, i.e. will only maintain a westerly direction if fired along the equator. See "Using great circles" Using great circles
  29. ^ Galileo, Dialogue Concerning the Two Chief World Systems, 1632 (full text).
  30. ^ Andrew Motte's English translation:Newton, Isaac (1846), Newton's Principia : the mathematical principles of natural philosophy, New York: Daniel Adee, p. 83 This usual statement of Newton's Law from the Motte-Cajori translation, is however misleading giving the impression that 'state' refers only to rest and not motion whereas it refers to both. So the comma should come after 'state' not 'rest' (Koyre: Newtonian Studies London 1965 Chap III, App A)
  31. ^ Alfred Engel English Translation:Einstein, Albert (1997), The Foundation of the General Theory of Relativity (PDF), New Jersey: Princeton University Press, retrieved 30 May 2014
  32. ^ Max Born; Günther Leibfried (1962). Einstein's Theory of Relativity. New York: Courier Dover Publications. p. 315. ISBN 0-486-60769-0. inertial motion.
  33. ^ Max Born (1922). "Einstein's Theory of Relativity - inertial motion, p. 252". New York, E. P. Dutton and company, publishers.
  34. ^ "inertia | Etymology, origin and meaning of inertia by etymonline". www.etymonline.com. Retrieved 2023-10-01.

Further reading edit

  • Butterfield, H (1957), The Origins of Modern Science, ISBN 0-7135-0160-X.
  • Clement, J (1982), "Students' preconceptions in introductory mechanics", American Journal of Physics vol 50, pp 66–71
  • Crombie, A C (1959), Medieval and Early Modern Science, vol. 2.
  • McCloskey, M (1983), "Intuitive physics", Scientific American, April, pp. 114–123.
  • McCloskey, M & Carmazza, A (1980), "Curvilinear motion in the absence of external forces: naïve beliefs about the motion of objects", Science vol. 210, pp. 1139–1141.
  • Pfister, Herbert; King, Markus (2015). Inertia and Gravitation. The Fundamental Nature and Structure of Space-Time. Vol. The Lecture Notes in Physics. Volume 897. Heidelberg: Springer. doi:10.1007/978-3-319-15036-9. ISBN 978-3-319-15035-2.
  • Ragep, F. Jamil (2001a). "Tusi and Copernicus: The Earth's Motion in Context". Science in Context. Cambridge University Press. 14 (1–2): 145–163. doi:10.1017/S0269889701000060. S2CID 145372613.
  • Ragep, F. Jamil (2001b). "Freeing Astronomy from Philosophy: An Aspect of Islamic Influence on Science". Osiris. 2nd Series. 16 (Science in Theistic Contexts: Cognitive Dimensions): 49–64 & 66–71. Bibcode:2001Osir...16...49R. doi:10.1086/649338. S2CID 142586786.

External links edit

  •   Quotations related to Inertia at Wikiquote
  • Why Does the Earth Spin? (YouTube)

February 15, 2024
inertia, this, article, about, inertia, physics, other, uses, disambiguation, tendency, objects, motion, stay, motion, objects, rest, stay, rest, unless, force, causes, speed, direction, change, fundamental, principles, classical, physics, described, isaac, ne. This article is about inertia in physics For other uses see Inertia disambiguation Inertia is the tendency of objects in motion to stay in motion and objects at rest to stay at rest unless a force causes its speed or direction to change It is one of the fundamental principles in classical physics and described by Isaac Newton in his first law of motion also known as The Principle of Inertia 1 It is one of the primary manifestations of mass one of the core quantitative properties of physical systems 2 Newton writes 3 4 LAW I Every object perseveres in its state of rest or of uniform motion in a right line except insofar as it is compelled to change that state by forces impressed thereon Isaac Newton Principa Translation by Cohen and Whitman 1999 In his 1687 work Philosophiae Naturalis Principia Mathematica Newton defined inertia as a force DEFINITION III The vis insita or innate force of matter is a power of resisting by which every body as much as in it lies endeavours to persevere in its present state whether it be of rest or of moving uniformly forward in a right line 5 Contents 1 History and development 1 1 Early understanding of inertial motion 1 2 Theory of impetus 1 3 Classical inertia 1 4 Relativity 2 Etymology 3 Rotational inertia 4 See also 5 References 6 Further reading 7 External linksHistory and development editEarly understanding of inertial motion edit Professor John H Lienhard points out the Mozi based on a Chinese text from the Warring States period 475 221 BCE as having given the first description of inertia 6 Before the European Renaissance the prevailing theory of motion in western philosophy was that of Aristotle 384 322 BCE On the surface of the Earth the inertia property of physical objects is often masked by gravity and the effects of friction and air resistance both of which tend to decrease the speed of moving objects commonly to the point of rest This misled the philosopher Aristotle to believe that objects would move only as long as force was applied to them 7 8 Aristotle said that all moving objects on Earth eventually come to rest unless an external power force continued to move them 9 Aristotle explained the continued motion of projectiles after being separated from their projector as an itself unexplained action of the surrounding medium continuing to move the projectile 10 Despite its general acceptance Aristotle s concept of motion 11 was disputed on several occasions by notable philosophers over nearly two millennia For example Lucretius following presumably Epicurus stated that the default state of the matter was motion not stasis stagnation 12 In the 6th century John Philoponus criticized the inconsistency between Aristotle s discussion of projectiles where the medium keeps projectiles going and his discussion of the void where the medium would hinder a body s motion Philoponus proposed that motion was not maintained by the action of a surrounding medium but by some property imparted to the object when it was set in motion Although this was not the modern concept of inertia for there was still the need for a power to keep a body in motion it proved a fundamental step in that direction 13 14 This view was strongly opposed by Averroes and by many scholastic philosophers who supported Aristotle However this view did not go unchallenged in the Islamic world where Philoponus had several supporters who further developed his ideas In the 11th century Persian polymath Ibn Sina Avicenna claimed that a projectile in a vacuum would not stop unless acted upon 15 Theory of impetus edit Main article Theory of impetus See also Conatus In the 14th century Jean Buridan rejected the notion that a motion generating property which he named impetus dissipated spontaneously Buridan s position was that a moving object would be arrested by the resistance of the air and the weight of the body which would oppose its impetus 16 Buridan also maintained that impetus increased with speed thus his initial idea of impetus was similar in many ways to the modern concept of momentum Despite the obvious similarities to more modern ideas of inertia Buridan saw his theory as only a modification to Aristotle s basic philosophy maintaining many other peripatetic views including the belief that there was still a fundamental difference between an object in motion and an object at rest Buridan also believed that impetus could be not only linear but also circular in nature causing objects such as celestial bodies to move in a circle Buridan s theory was followed up by his pupil Albert of Saxony 1316 1390 and the Oxford Calculators who performed various experiments which further undermined the Aristotelian model Their work in turn was elaborated by Nicole Oresme who pioneered the practice of illustrating the laws of motion with graphs Shortly before Galileo s theory of inertia Giambattista Benedetti modified the growing theory of impetus to involve linear motion alone Any portion of corporeal matter which moves by itself when an impetus has been impressed on it by any external motive force has a natural tendency to move on a rectilinear not a curved path 17 Benedetti cites the motion of a rock in a sling as an example of the inherent linear motion of objects forced into circular motion Classical inertia edit According to Charles Coulston Gillispie inertia entered science as a physical consequence of Descartes geometrization of space matter combined with the immutability of God 18 The first physicist to completely break away from the Aristotelian model of motion was Isaac Beeckman in 1614 19 The term inertia was first introduced by Johannes Kepler in his Epitome Astronomiae Copernicanae 20 published in three parts from 1617 to 1621 however the meaning of Kepler s term which he derived from the Latin word for idleness or laziness was not quite the same as its modern interpretation Kepler defined inertia only in terms of resistance to movement once again based on the presumption that rest was a natural state which did not need explanation It was not until the later work of Galileo and Newton unified rest and motion in one principle that the term inertia could be applied to these concepts as it is today 21 The principle of inertia as formulated by Aristotle for motions in a void 22 includes that a mundane object tends to resist a change in motion The Aristotelian division of motion into mundane and celestial became increasingly problematic in the face of the conclusions of Nicolaus Copernicus in the 16th century who argued that the Earth is never at rest but is actually in constant motion around the Sun 23 nbsp Isaac Newton 1689 nbsp Galileo GalileiGalileo in his further development of the Copernican model recognized these problems with the then accepted nature of motion and at least partially as a result included a restatement of Aristotle s description of motion in a void as a basic physical principle A body moving on a level surface will continue in the same direction at a constant speed unless disturbed Galileo writes that all external impediments removed a heavy body on a spherical surface concentric with the earth will maintain itself in that state in which it has been if placed in a movement towards the west for example it will maintain itself in that movement 24 This notion which is termed circular inertia or horizontal circular inertia by historians of science is a precursor to but is distinct from Newton s notion of rectilinear inertia 25 26 For Galileo a motion is horizontal if it does not carry the moving body towards or away from the center of the Earth and for him a ship for instance having once received some impetus through the tranquil sea would move continually around our globe without ever stopping 27 28 It is also worth noting that Galileo later in 1632 concluded that based on this initial premise of inertia it is impossible to tell the difference between a moving object and a stationary one without some outside reference to compare it against 29 This observation ultimately came to be the basis for Albert Einstein to develop the theory of special relativity Concepts of inertia in Galileo s writings would later come to be refined modified and codified by Isaac Newton as the first of his Laws of Motion first published in Newton s work Philosophiae Naturalis Principia Mathematica in 1687 Every body perseveres in its state of rest or of uniform motion in a right line unless it is compelled to change that state by forces impressed thereon 30 Despite having defined the concept in his laws of motion Newton did not actually use the term inertia In fact originally he viewed the respective phenomenon as being caused by innate forces inherent in matter which resisted any acceleration Given this perspective and borrowing from Kepler Newton attributed the term inertia to mean the innate force possessed by an object which resists changes in motion thus Newton defined inertia to mean the cause of the phenomenon rather than the phenomenon itself However Newton s original ideas of innate resistive force were ultimately problematic for a variety of reasons and thus most physicists no longer think in these terms As no alternate mechanism has been readily accepted and it is now generally accepted that there may not be one that we can know the term inertia has come to mean simply the phenomenon itself rather than any inherent mechanism Thus ultimately inertia in modern classical physics has come to be a name for the same phenomenon as described by Newton s First Law of Motion and the two concepts are now considered to be equivalent nbsp The effect of inertial mass if pulled slowly the upper thread breaks a If pulled quickly the lower thread breaks b Relativity edit Albert Einstein s theory of special relativity as proposed in his 1905 paper entitled On the Electrodynamics of Moving Bodies was built on the understanding of inertial reference frames developed by Galileo Huygens and Newton While this revolutionary theory did significantly change the meaning of many Newtonian concepts such as mass energy and distance Einstein s concept of inertia remained at first unchanged from Newton s original meaning However this resulted in a limitation inherent in special relativity the principle of relativity could only apply to inertial reference frames To address this limitation Einstein developed his general theory of relativity The Foundation of the General Theory of Relativity 1916 which provided a theory including noninertial accelerated reference frames 31 In general relativity the concept of inertial motion got a broader meaning Taking into account general relativity inertial motion is any movement of a body that is not affected by forces of electrical magnetic or other origin but that is only under the influence of gravitational masses 32 33 Physically speaking this happens to be exactly what a properly functioning three axis accelerometer is indicating when it does not detect any proper acceleration Etymology editThe term inertia comes from the Latin word iners meaning idle or sluggish 34 Rotational inertia editA quantity related to inertia is rotational inertia moment of inertia the property that a rotating rigid body maintains its state of uniform rotational motion Its angular momentum remains unchanged unless an external torque is applied this is called conservation of angular momentum Rotational inertia is often considered in relation to a rigid body For example a gyroscope uses the property that it resists any change in the axis of rotation See also editFlywheel energy storage devices which may also be known as an Inertia battery General relativity Vertical and horizontal Inertial navigation system Inertial response of synchronous generators in an electrical grid Kinetic energy List of moments of inertia Mach s principle Newton s laws of motion Classical mechanics Special relativity Parallel axis theoremReferences edit Britannica Dictionary definition of INERTIA Retrieved 2022 07 08 Britannica Science inertia physics Retrieved 2022 07 08 Andrew Motte s English translation Newton Isaac 1846 Newton s Principia the mathematical principles of natural philosophy 3rd edition New York Daniel Adee p 83 What Newton really meant Daniel Hoek IAI TV Changing how the world thinks 2023 08 17 Retrieved 2023 09 29 Andrew Motte s English translation Newton Isaac 1846 Newton s Principia the mathematical principles of natural philosophy 3rd edition New York Daniel Adee p 73 No 2080 The Survival of Invention www uh edu Aristotle Minor works 1936 Mechanical Problems Mechanica University of Chicago Library Loeb Classical Library Cambridge Mass and London p 407 it a body stops when the force which is pushing the travelling object has no longer power to push it along Pages 2 to 4 Section 1 1 Skating Chapter 1 Things that Move Louis Bloomfield Professor of Physics at the University of Virginia How Everything Works Making Physics Out of the Ordinary John Wiley amp Sons 2007 hardcover ISBN 978 0 471 74817 5 Byrne Christopher 2018 Aristotle s Science of Matter and Motion University of Toronto Press p 21 ISBN 978 1 4875 0396 3 Extract of page 21 Aristotle Physics 8 10 267a1 21 Aristotle Physics trans by R P Hardie and R K Gaye projectile Archived 2007 01 29 at the Wayback Machine Darling David 2006 Gravity s arc the story of gravity from Aristotle to Einstein and beyond John Wiley and Sons pp 17 50 ISBN 978 0 471 71989 2 Lucretius On the Nature of Things London Penguin 1988 pp 80 85 all must move Sorabji Richard 1988 Matter space and motion theories in antiquity and their sequel 1st ed Ithaca N Y Cornell University Press pp 227 228 ISBN 978 0801421945 John Philoponus Stanford Encyclopedia of Philosophy 8 June 2007 Retrieved 26 July 2012 Espinoza Fernando An Analysis of the Historical Development of Ideas About Motion and its Implications for Teaching Physics Education Vol 40 2 Medieval thought Jean Buridan Quaestiones on Aristotle s Physics quoted at Impetus Theory Stillman Drake Essays on Galileo etc Vol 3 p 285 Gillispie Charles Coulston 1960 The Edge of Objectivity An Essay in the History of Scientific Ideas Princeton University Press pp 367 68 ISBN 0 691 02350 6 van Berkel Klaas 2013 Isaac Beeckman on Matter and Motion Mechanical Philosophy in the Making Johns Hopkins University Press pp 105 110 ISBN 9781421409368 Lawrence Nolan ed The Cambridge Descartes Lexicon Cambridge University Press 2016 Inertia p 405 Biad Abder Rahim 2018 01 26 Restoring the Bioelectrical Machine Lulu Press Inc ISBN 9781365447709 7th paragraph of section 8 book 4 of Physica Nicholas Copernicus The Revolutions of the Heavenly Spheres 1543 Drake Stillman Galilei s presentation of his principle of inertia p 113 Retrieved 2022 07 31 See Alan Chalmers article Galilean Relativity and Galileo s Relativity in Correspondence Invariance and Heuristics Essays in Honour of Heinz Post eds Steven French and Harmke Kamminga Kluwer Academic Publishers Dordrecht 1991 pp 199 200 ISBN 0792320859 Chalmers does not however believe that Galileo s physics had a general principle of inertia circular or otherwise page 199 Dijksterhuis E J The Mechanisation of the World Picture Oxford University Press Oxford 1961 p 352 Drake Stillman Discoveries and Opinions of Galileo p 113 114 Retrieved 2022 07 31 According to Newtonian mechanics if a projectile on a smooth spherical planet is given an initial horizontal velocity it will not remain on the surface of the planet Various curves are possible depending on the initial speed and the height of the launch See Harris Benson University Physics New York 1991 page 268 If constrained to remain on the surface by being sandwiched say in between two concentric spheres it will follow a great circle on the surface of the earth i e will only maintain a westerly direction if fired along the equator See Using great circles Using great circles Galileo Dialogue Concerning the Two Chief World Systems 1632 full text Andrew Motte s English translation Newton Isaac 1846 Newton s Principia the mathematical principles of natural philosophy New York Daniel Adee p 83 This usual statement of Newton s Law from the Motte Cajori translation is however misleading giving the impression that state refers only to rest and not motion whereas it refers to both So the comma should come after state not rest Koyre Newtonian Studies London 1965 Chap III App A Alfred Engel English Translation Einstein Albert 1997 The Foundation of the General Theory of Relativity PDF New Jersey Princeton University Press retrieved 30 May 2014 Max Born Gunther Leibfried 1962 Einstein s Theory of Relativity New York Courier Dover Publications p 315 ISBN 0 486 60769 0 inertial motion Max Born 1922 Einstein s Theory of Relativity inertial motion p 252 New York E P Dutton and company publishers inertia Etymology origin and meaning of inertia by etymonline www etymonline com Retrieved 2023 10 01 Further reading editButterfield H 1957 The Origins of Modern Science ISBN 0 7135 0160 X Clement J 1982 Students preconceptions in introductory mechanics American Journal of Physics vol 50 pp 66 71 Crombie A C 1959 Medieval and Early Modern Science vol 2 McCloskey M 1983 Intuitive physics Scientific American April pp 114 123 McCloskey M amp Carmazza A 1980 Curvilinear motion in the absence of external forces naive beliefs about the motion of objects Science vol 210 pp 1139 1141 Pfister Herbert King Markus 2015 Inertia and Gravitation The Fundamental Nature and Structure of Space Time Vol The Lecture Notes in Physics Volume 897 Heidelberg Springer doi 10 1007 978 3 319 15036 9 ISBN 978 3 319 15035 2 Ragep F Jamil 2001a Tusi and Copernicus The Earth s Motion in Context Science in Context Cambridge University Press 14 1 2 145 163 doi 10 1017 S0269889701000060 S2CID 145372613 Ragep F Jamil 2001b Freeing Astronomy from Philosophy An Aspect of Islamic Influence on Science Osiris 2nd Series 16 Science in Theistic Contexts Cognitive Dimensions 49 64 amp 66 71 Bibcode 2001Osir 16 49R doi 10 1086 649338 S2CID 142586786 External links edit nbsp Quotations related to Inertia at Wikiquote Why Does the Earth Spin YouTube Retrieved from https en wikipedia org w index php title Inertia amp oldid 1201462171, wikipedia, wiki, book, books, library,

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