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Mechanics

April 15, 2023

This article is about an area of scientific study. For other uses, see Mechanic (disambiguation).

Mechanics (from Ancient Greek: μηχανική, mēkhanikḗ, lit. "of machines")[1][2] is the area of mathematics and physics concerned with the relationships between force, matter, and motion among physical objects.[3] Forces applied to objects result in displacements or changes of an object's position relative to its environment.

Theoretical expositions of this branch of physics has its origins in Ancient Greece, for instance, in the writings of Aristotle and Archimedes[4][5][6] (see History of classical mechanics and Timeline of classical mechanics). During the early modern period, scientists such as Galileo, Kepler, Huygens, and Newton laid the foundation for what is now known as classical mechanics.

As a branch of classical physics, mechanics deals with bodies that are either at rest or are moving with velocities significantly less than the speed of light. It can also be defined as the physical science that deals with the motion of and forces on bodies not in the quantum realm.

History

Main articles: History of classical mechanics and History of quantum mechanics

Antiquity

Main article: Aristotelian mechanics

The ancient Greek philosophers were among the first to propose that abstract principles govern nature. The main theory of mechanics in antiquity was Aristotelian mechanics, though an alternative theory is exposed in the pseudo-Aristotelian Mechanical Problems, often attributed to one of his successors.

There is another tradition that goes back to the ancient Greeks where mathematics is used more extensively to analyze bodies statically or dynamically, an approach that may have been stimulated by prior work of the Pythagorean Archytas.[7] Examples of this tradition include pseudo-Euclid (On the Balance), Archimedes (On the Equilibrium of Planes, On Floating Bodies), Hero (Mechanica), and Pappus (Collection, Book VIII).[8][9]

Medieval age

Main article: Theory of impetus
 
Arabic machine in a manuscript of unknown date.

In the Middle Ages, Aristotle's theories were criticized and modified by a number of figures, beginning with John Philoponus in the 6th century. A central problem was that of projectile motion, which was discussed by Hipparchus and Philoponus.

Persian Islamic polymath Ibn Sīnā published his theory of motion in The Book of Healing (1020). He said that an impetus is imparted to a projectile by the thrower, and viewed it as persistent, requiring external forces such as air resistance to dissipate it.[10][11][12] Ibn Sina made distinction between 'force' and 'inclination' (called "mayl"), and argued that an object gained mayl when the object is in opposition to its natural motion. So he concluded that continuation of motion is attributed to the inclination that is transferred to the object, and that object will be in motion until the mayl is spent. He also claimed that a projectile in a vacuum would not stop unless it is acted upon, consistent with Newton's first law of motion.[13]

On the question of a body subject to a constant (uniform) force, the 12th-century Jewish-Arab scholar Hibat Allah Abu'l-Barakat al-Baghdaadi (born Nathanel, Iraqi, of Baghdad) stated that constant force imparts constant acceleration. According to Shlomo Pines, al-Baghdaadi's theory of motion was "the oldest negation of Aristotle's fundamental dynamic law [namely, that a constant force produces a uniform motion], [and is thus an] anticipation in a vague fashion of the fundamental law of classical mechanics [namely, that a force applied continuously produces acceleration]."[14]

Influenced by earlier writers such as Ibn Sina[15] and al-Baghdaadi,[16] the 14th-century French priest Jean Buridan developed the theory of impetus, which later developed into the modern theories of inertia, velocity, acceleration and momentum. This work and others was developed in 14th-century England by the Oxford Calculators such as Thomas Bradwardine, who studied and formulated various laws regarding falling bodies. The concept that the main properties of a body are uniformly accelerated motion (as of falling bodies) was worked out by the 14th-century Oxford Calculators.

Early modern age

 
First European depiction of a piston pump, by Taccola, c. 1450.[17]

Two central figures in the early modern age are Galileo Galilei and Isaac Newton. Galileo's final statement of his mechanics, particularly of falling bodies, is his Two New Sciences (1638). Newton's 1687 Philosophiæ Naturalis Principia Mathematica provided a detailed mathematical account of mechanics, using the newly developed mathematics of calculus and providing the basis of Newtonian mechanics.[9]

There is some dispute over priority of various ideas: Newton's Principia is certainly the seminal work and has been tremendously influential, and many of the mathematics results therein could not have been stated earlier without the development of the calculus. However, many of the ideas, particularly as pertain to inertia and falling bodies, had been developed by prior scholars such as Christiaan Huygens and the less-known medieval predecessors. Precise credit is at times difficult or contentious because scientific language and standards of proof changed, so whether medieval statements are equivalent to modern statements or sufficient proof, or instead similar to modern statements and hypotheses is often debatable.

Modern age

Two main modern developments in mechanics are general relativity of Einstein, and quantum mechanics, both developed in the 20th century based in part on earlier 19th-century ideas. The development in the modern continuum mechanics, particularly in the areas of elasticity, plasticity, fluid dynamics, electrodynamics and thermodynamics of deformable media, started in the second half of the 20th century.

Types of mechanical bodies

The often-used term body needs to stand for a wide assortment of objects, including particles, projectiles, spacecraft, stars, parts of machinery, parts of solids, parts of fluids (gases and liquids), etc.

Other distinctions between the various sub-disciplines of mechanics, concern the nature of the bodies being described. Particles are bodies with little (known) internal structure, treated as mathematical points in classical mechanics. Rigid bodies have size and shape, but retain a simplicity close to that of the particle, adding just a few so-called degrees of freedom, such as orientation in space.

Otherwise, bodies may be semi-rigid, i.e. elastic, or non-rigid, i.e. fluid. These subjects have both classical and quantum divisions of study.

For instance, the motion of a spacecraft, regarding its orbit and attitude (rotation), is described by the relativistic theory of classical mechanics, while the analogous movements of an atomic nucleus are described by quantum mechanics.

Sub-disciplines

The following are two lists of various subjects that are studied in mechanics.

Note that there is also the "theory of fields" which constitutes a separate discipline in physics, formally treated as distinct from mechanics, whether classical fields or quantum fields. But in actual practice, subjects belonging to mechanics and fields are closely interwoven. Thus, for instance, forces that act on particles are frequently derived from fields (electromagnetic or gravitational), and particles generate fields by acting as sources. In fact, in quantum mechanics, particles themselves are fields, as described theoretically by the wave function.

Classical

Prof. Walter Lewin explains Newton's law of gravitation in MIT course 8.01.[18]

The following are described as forming classical mechanics:

Quantum

The following are categorized as being part of quantum mechanics:

Historically, classical mechanics had been around for nearly a quarter millennium before quantum mechanics developed. Classical mechanics originated with Isaac Newton's laws of motion in Philosophiæ Naturalis Principia Mathematica, developed over the seventeenth century. Quantum mechanics developed later, over the nineteenth century, precipitated by Planck's postulate and Albert Einstein's explanation of the photoelectric effect. Both fields are commonly held to constitute the most certain knowledge that exists about physical nature.

Classical mechanics has especially often been viewed as a model for other so-called exact sciences. Essential in this respect is the extensive use of mathematics in theories, as well as the decisive role played by experiment in generating and testing them.

Quantum mechanics is of a bigger scope, as it encompasses classical mechanics as a sub-discipline which applies under certain restricted circumstances. According to the correspondence principle, there is no contradiction or conflict between the two subjects, each simply pertains to specific situations. The correspondence principle states that the behavior of systems described by quantum theories reproduces classical physics in the limit of large quantum numbers, i.e. if quantum mechanics is applied to large systems (for e.g. a baseball), the result would almost be the same if classical mechanics had been applied. Quantum mechanics has superseded classical mechanics at the foundation level and is indispensable for the explanation and prediction of processes at the molecular, atomic, and sub-atomic level. However, for macroscopic processes classical mechanics is able to solve problems which are unmanageably difficult (mainly due to computational limits) in quantum mechanics and hence remains useful and well used. Modern descriptions of such behavior begin with a careful definition of such quantities as displacement (distance moved), time, velocity, acceleration, mass, and force. Until about 400 years ago, however, motion was explained from a very different point of view. For example, following the ideas of Greek philosopher and scientist Aristotle, scientists reasoned that a cannonball falls down because its natural position is in the Earth; the sun, the moon, and the stars travel in circles around the earth because it is the nature of heavenly objects to travel in perfect circles.

Often cited as father to modern science, Galileo brought together the ideas of other great thinkers of his time and began to calculate motion in terms of distance travelled from some starting position and the time that it took. He showed that the speed of falling objects increases steadily during the time of their fall. This acceleration is the same for heavy objects as for light ones, provided air friction (air resistance) is discounted. The English mathematician and physicist Isaac Newton improved this analysis by defining force and mass and relating these to acceleration. For objects traveling at speeds close to the speed of light, Newton's laws were superseded by Albert Einstein's theory of relativity. [A sentence illustrating the computational complication of Einstein's theory of relativity.] For atomic and subatomic particles, Newton's laws were superseded by quantum theory. For everyday phenomena, however, Newton's three laws of motion remain the cornerstone of dynamics, which is the study of what causes motion.

Relativistic

Akin to the distinction between quantum and classical mechanics, Albert Einstein's general and special theories of relativity have expanded the scope of Newton and Galileo's formulation of mechanics. The differences between relativistic and Newtonian mechanics become significant and even dominant as the velocity of a body approaches the speed of light. For instance, in Newtonian mechanics, the kinetic energy of a free particle is E = 1/2mv2, whereas in relativistic mechanics, it is E = (γ − 1)mc2 (where γ is the Lorentz factor; this formula reduces to the Newtonian expression in the low energy limit).[19]

For high-energy processes, quantum mechanics must be adjusted to account for special relativity; this has led to the development of quantum field theory.[20]

Professional organizations

See also

References

  1. ^ "mechanics". Oxford English Dictionary. 1933.
  2. ^ Liddell, Scott, Jones (1940). "mechanics". A Greek-English Lexicon.{{cite encyclopedia}}: CS1 maint: uses authors parameter (link)
  3. ^ Young, Hugh D. (Hugh David), 1930- (2 September 2019). Sears and Zemansky's university physics : with modern physics. Freedman, Roger A., Ford, A. Lewis (Albert Lewis), Estrugo, Katarzyna Zulteta (Fifteenth edition in SI units ed.). Harlow. p. 62. ISBN 978-1-292-31473-0. OCLC 1104689918.{{cite book}}: CS1 maint: multiple names: authors list (link)
  4. ^ Dugas, Rene. A History of Classical Mechanics. New York, NY: Dover Publications Inc, 1988, pg 19.
  5. ^ Rana, N.C., and Joag, P.S. Classical Mechanics. West Petal Nagar, New Delhi. Tata McGraw-Hill, 1991, pg 6.
  6. ^ Renn, J., Damerow, P., and McLaughlin, P. Aristotle, Archimedes, Euclid, and the Origin of Mechanics: The Perspective of Historical Epistemology. Berlin: Max Planck Institute for the History of Science, 2010, pg 1-2.
  7. ^ Zhmud, L. (2012). Pythagoras and the Early Pythagoreans. OUP Oxford. ISBN 978-0-19-928931-8.
  8. ^ "A history of mechanics". René Dugas (1988). p.19. ISBN 0-486-65632-2
  9. ^ a b "A Tiny Taste of the History of Mechanics". The University of Texas at Austin.
  10. ^ Espinoza, Fernando (2005). "An analysis of the historical development of ideas about motion and its implications for teaching". Physics Education. 40 (2): 141. Bibcode:2005PhyEd..40..139E. doi:10.1088/0031-9120/40/2/002. S2CID 250809354.
  11. ^ Seyyed Hossein Nasr & Mehdi Amin Razavi (1996). The Islamic intellectual tradition in Persia. Routledge. p. 72. ISBN 978-0-7007-0314-2.
  12. ^ Aydin Sayili (1987). "Ibn Sīnā and Buridan on the Motion of the Projectile". Annals of the New York Academy of Sciences. 500 (1): 477–482. Bibcode:1987NYASA.500..477S. doi:10.1111/j.1749-6632.1987.tb37219.x. S2CID 84784804.
  13. ^ Espinoza, Fernando. "An Analysis of the Historical Development of Ideas About Motion and its Implications for Teaching". Physics Education. Vol. 40(2).
  14. ^ Pines, Shlomo (1970). "Abu'l-Barakāt al-Baghdādī , Hibat Allah". Dictionary of Scientific Biography. Vol. 1. New York: Charles Scribner's Sons. pp. 26–28. ISBN 0-684-10114-9.
    (cf. Abel B. Franco (October 2003). "Avempace, Projectile Motion, and Impetus Theory", Journal of the History of Ideas 64 (4), p. 521-546 [528].)
  15. ^ Sayili, Aydin. "Ibn Sina and Buridan on the Motion the Projectile". Annals of the New York Academy of Sciences vol. 500(1). p.477-482.
  16. ^ Gutman, Oliver (2003), Pseudo-Avicenna, Liber Celi Et Mundi: A Critical Edition, Brill Publishers, p. 193, ISBN 90-04-13228-7
  17. ^ Hill, Donald Routledge (1996). A History of Engineering in Classical and Medieval Times. London: Routledge. p. 143. ISBN 0-415-15291-7.
  18. ^ Walter Lewin (October 4, 1999). Work, Energy, and Universal Gravitation. MIT Course 8.01: Classical Mechanics, Lecture 11 (ogg) (videotape). Cambridge, MA US: MIT OCW. Event occurs at 1:21-10:10. Retrieved December 23, 2010.
  19. ^ Landau, L.; Lifshitz, E. (January 15, 1980). The Classical Theory of Fields (4th Revised English ed.). Butterworth-Heinemann. p. 27.
  20. ^ Weinberg, S. (May 1, 2005). The Quantum Theory of Fields, Volume 1: Foundations (1st ed.). Cambridge University Press. p. xxi. ISBN 0521670535.

Further reading

External links

 
Look up mechanics in Wiktionary, the free dictionary.
  • Mechanics Definition
  • Mechanics Blog by a Purdue University Professor
  • from the University of New South Wales

April 15, 2023
mechanics, this, article, about, area, scientific, study, other, uses, mechanic, disambiguation, from, ancient, greek, μηχανική, mēkhanikḗ, machines, area, mathematics, physics, concerned, with, relationships, between, force, matter, motion, among, physical, o. This article is about an area of scientific study For other uses see Mechanic disambiguation Mechanics from Ancient Greek mhxanikh mekhanikḗ lit of machines 1 2 is the area of mathematics and physics concerned with the relationships between force matter and motion among physical objects 3 Forces applied to objects result in displacements or changes of an object s position relative to its environment Theoretical expositions of this branch of physics has its origins in Ancient Greece for instance in the writings of Aristotle and Archimedes 4 5 6 see History of classical mechanics and Timeline of classical mechanics During the early modern period scientists such as Galileo Kepler Huygens and Newton laid the foundation for what is now known as classical mechanics As a branch of classical physics mechanics deals with bodies that are either at rest or are moving with velocities significantly less than the speed of light It can also be defined as the physical science that deals with the motion of and forces on bodies not in the quantum realm Contents 1 History 1 1 Antiquity 1 2 Medieval age 1 3 Early modern age 1 4 Modern age 2 Types of mechanical bodies 3 Sub disciplines 3 1 Classical 3 2 Quantum 3 3 Relativistic 4 Professional organizations 5 See also 6 References 7 Further reading 8 External linksHistory EditMain articles History of classical mechanics and History of quantum mechanics Antiquity Edit Main article Aristotelian mechanics The ancient Greek philosophers were among the first to propose that abstract principles govern nature The main theory of mechanics in antiquity was Aristotelian mechanics though an alternative theory is exposed in the pseudo Aristotelian Mechanical Problems often attributed to one of his successors There is another tradition that goes back to the ancient Greeks where mathematics is used more extensively to analyze bodies statically or dynamically an approach that may have been stimulated by prior work of the Pythagorean Archytas 7 Examples of this tradition include pseudo Euclid On the Balance Archimedes On the Equilibrium of Planes On Floating Bodies Hero Mechanica and Pappus Collection Book VIII 8 9 Medieval age Edit Main article Theory of impetus Arabic machine in a manuscript of unknown date In the Middle Ages Aristotle s theories were criticized and modified by a number of figures beginning with John Philoponus in the 6th century A central problem was that of projectile motion which was discussed by Hipparchus and Philoponus Persian Islamic polymath Ibn Sina published his theory of motion in The Book of Healing 1020 He said that an impetus is imparted to a projectile by the thrower and viewed it as persistent requiring external forces such as air resistance to dissipate it 10 11 12 Ibn Sina made distinction between force and inclination called mayl and argued that an object gained mayl when the object is in opposition to its natural motion So he concluded that continuation of motion is attributed to the inclination that is transferred to the object and that object will be in motion until the mayl is spent He also claimed that a projectile in a vacuum would not stop unless it is acted upon consistent with Newton s first law of motion 13 On the question of a body subject to a constant uniform force the 12th century Jewish Arab scholar Hibat Allah Abu l Barakat al Baghdaadi born Nathanel Iraqi of Baghdad stated that constant force imparts constant acceleration According to Shlomo Pines al Baghdaadi s theory of motion was the oldest negation of Aristotle s fundamental dynamic law namely that a constant force produces a uniform motion and is thus an anticipation in a vague fashion of the fundamental law of classical mechanics namely that a force applied continuously produces acceleration 14 Influenced by earlier writers such as Ibn Sina 15 and al Baghdaadi 16 the 14th century French priest Jean Buridan developed the theory of impetus which later developed into the modern theories of inertia velocity acceleration and momentum This work and others was developed in 14th century England by the Oxford Calculators such as Thomas Bradwardine who studied and formulated various laws regarding falling bodies The concept that the main properties of a body are uniformly accelerated motion as of falling bodies was worked out by the 14th century Oxford Calculators Early modern age Edit First European depiction of a piston pump by Taccola c 1450 17 Two central figures in the early modern age are Galileo Galilei and Isaac Newton Galileo s final statement of his mechanics particularly of falling bodies is his Two New Sciences 1638 Newton s 1687 Philosophiae Naturalis Principia Mathematica provided a detailed mathematical account of mechanics using the newly developed mathematics of calculus and providing the basis of Newtonian mechanics 9 There is some dispute over priority of various ideas Newton s Principia is certainly the seminal work and has been tremendously influential and many of the mathematics results therein could not have been stated earlier without the development of the calculus However many of the ideas particularly as pertain to inertia and falling bodies had been developed by prior scholars such as Christiaan Huygens and the less known medieval predecessors Precise credit is at times difficult or contentious because scientific language and standards of proof changed so whether medieval statements are equivalent to modern statements or sufficient proof or instead similar to modern statements and hypotheses is often debatable Modern age Edit Two main modern developments in mechanics are general relativity of Einstein and quantum mechanics both developed in the 20th century based in part on earlier 19th century ideas The development in the modern continuum mechanics particularly in the areas of elasticity plasticity fluid dynamics electrodynamics and thermodynamics of deformable media started in the second half of the 20th century Types of mechanical bodies EditThe often used term body needs to stand for a wide assortment of objects including particles projectiles spacecraft stars parts of machinery parts of solids parts of fluids gases and liquids etc Other distinctions between the various sub disciplines of mechanics concern the nature of the bodies being described Particles are bodies with little known internal structure treated as mathematical points in classical mechanics Rigid bodies have size and shape but retain a simplicity close to that of the particle adding just a few so called degrees of freedom such as orientation in space Otherwise bodies may be semi rigid i e elastic or non rigid i e fluid These subjects have both classical and quantum divisions of study For instance the motion of a spacecraft regarding its orbit and attitude rotation is described by the relativistic theory of classical mechanics while the analogous movements of an atomic nucleus are described by quantum mechanics Sub disciplines EditThe following are two lists of various subjects that are studied in mechanics Note that there is also the theory of fields which constitutes a separate discipline in physics formally treated as distinct from mechanics whether classical fields or quantum fields But in actual practice subjects belonging to mechanics and fields are closely interwoven Thus for instance forces that act on particles are frequently derived from fields electromagnetic or gravitational and particles generate fields by acting as sources In fact in quantum mechanics particles themselves are fields as described theoretically by the wave function Classical Edit source source source source source source Prof Walter Lewin explains Newton s law of gravitation in MIT course 8 01 18 The following are described as forming classical mechanics Newtonian mechanics the original theory of motion kinematics and forces dynamics Analytical mechanics is a reformulation of Newtonian mechanics with an emphasis on system energy rather than on forces There are two main branches of analytical mechanics Hamiltonian mechanics a theoretical formalism based on the principle of conservation of energy Lagrangian mechanics another theoretical formalism based on the principle of the least action Classical statistical mechanics generalizes ordinary classical mechanics to consider systems in an unknown state often used to derive thermodynamic properties Celestial mechanics the motion of bodies in space planets comets stars galaxies etc Astrodynamics spacecraft navigation etc Solid mechanics elasticity plasticity viscoelasticity exhibited by deformable solids Fracture mechanics Acoustics sound density variation propagation in solids fluids and gases Statics semi rigid bodies in mechanical equilibrium Fluid mechanics the motion of fluids Soil mechanics mechanical behavior of soils Continuum mechanics mechanics of continua both solid and fluid Hydraulics mechanical properties of liquids Fluid statics liquids in equilibrium Applied mechanics or Engineering mechanics Biomechanics solids fluids etc in biology Biophysics physical processes in living organisms Relativistic or Einsteinian mechanics universal gravitation Quantum Edit The following are categorized as being part of quantum mechanics Schrodinger wave mechanics used to describe the movements of the wavefunction of a single particle Matrix mechanics is an alternative formulation that allows considering systems with a finite dimensional state space Quantum statistical mechanics generalizes ordinary quantum mechanics to consider systems in an unknown state often used to derive thermodynamic properties Particle physics the motion structure and reactions of particles Nuclear physics the motion structure and reactions of nuclei Condensed matter physics quantum gases solids liquids etc Historically classical mechanics had been around for nearly a quarter millennium before quantum mechanics developed Classical mechanics originated with Isaac Newton s laws of motion in Philosophiae Naturalis Principia Mathematica developed over the seventeenth century Quantum mechanics developed later over the nineteenth century precipitated by Planck s postulate and Albert Einstein s explanation of the photoelectric effect Both fields are commonly held to constitute the most certain knowledge that exists about physical nature Classical mechanics has especially often been viewed as a model for other so called exact sciences Essential in this respect is the extensive use of mathematics in theories as well as the decisive role played by experiment in generating and testing them Quantum mechanics is of a bigger scope as it encompasses classical mechanics as a sub discipline which applies under certain restricted circumstances According to the correspondence principle there is no contradiction or conflict between the two subjects each simply pertains to specific situations The correspondence principle states that the behavior of systems described by quantum theories reproduces classical physics in the limit of large quantum numbers i e if quantum mechanics is applied to large systems for e g a baseball the result would almost be the same if classical mechanics had been applied Quantum mechanics has superseded classical mechanics at the foundation level and is indispensable for the explanation and prediction of processes at the molecular atomic and sub atomic level However for macroscopic processes classical mechanics is able to solve problems which are unmanageably difficult mainly due to computational limits in quantum mechanics and hence remains useful and well used Modern descriptions of such behavior begin with a careful definition of such quantities as displacement distance moved time velocity acceleration mass and force Until about 400 years ago however motion was explained from a very different point of view For example following the ideas of Greek philosopher and scientist Aristotle scientists reasoned that a cannonball falls down because its natural position is in the Earth the sun the moon and the stars travel in circles around the earth because it is the nature of heavenly objects to travel in perfect circles Often cited as father to modern science Galileo brought together the ideas of other great thinkers of his time and began to calculate motion in terms of distance travelled from some starting position and the time that it took He showed that the speed of falling objects increases steadily during the time of their fall This acceleration is the same for heavy objects as for light ones provided air friction air resistance is discounted The English mathematician and physicist Isaac Newton improved this analysis by defining force and mass and relating these to acceleration For objects traveling at speeds close to the speed of light Newton s laws were superseded by Albert Einstein s theory of relativity A sentence illustrating the computational complication of Einstein s theory of relativity For atomic and subatomic particles Newton s laws were superseded by quantum theory For everyday phenomena however Newton s three laws of motion remain the cornerstone of dynamics which is the study of what causes motion Relativistic Edit Akin to the distinction between quantum and classical mechanics Albert Einstein s general and special theories of relativity have expanded the scope of Newton and Galileo s formulation of mechanics The differences between relativistic and Newtonian mechanics become significant and even dominant as the velocity of a body approaches the speed of light For instance in Newtonian mechanics the kinetic energy of a free particle is E 1 2 mv2 whereas in relativistic mechanics it is E g 1 mc2 where g is the Lorentz factor this formula reduces to the Newtonian expression in the low energy limit 19 For high energy processes quantum mechanics must be adjusted to account for special relativity this has led to the development of quantum field theory 20 Professional organizations EditApplied Mechanics Division American Society of Mechanical Engineers Fluid Dynamics Division American Physical Society Society for Experimental Mechanics Institution of Mechanical Engineers is the United Kingdom s qualifying body for mechanical engineers and has been the home of Mechanical Engineers for over 150 years International Union of Theoretical and Applied MechanicsSee also EditApplied mechanics Dynamics Engineering Index of engineering science and mechanics articles Kinematics Kinetics Non autonomous mechanics Statics Wiesen Test of Mechanical Aptitude WTMA References Edit mechanics Oxford English Dictionary 1933 Liddell Scott Jones 1940 mechanics A Greek English Lexicon a href Template Cite encyclopedia html title Template Cite encyclopedia cite encyclopedia a CS1 maint uses authors parameter link Young Hugh D Hugh David 1930 2 September 2019 Sears and Zemansky s university physics with modern physics Freedman Roger A Ford A Lewis Albert Lewis Estrugo Katarzyna Zulteta Fifteenth edition in SI units ed Harlow p 62 ISBN 978 1 292 31473 0 OCLC 1104689918 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link Dugas Rene A History of Classical Mechanics New York NY Dover Publications Inc 1988 pg 19 Rana N C and Joag P S Classical Mechanics West Petal Nagar New Delhi Tata McGraw Hill 1991 pg 6 Renn J Damerow P and McLaughlin P Aristotle Archimedes Euclid and the Origin of Mechanics The Perspective of Historical Epistemology Berlin Max Planck Institute for the History of Science 2010 pg 1 2 Zhmud L 2012 Pythagoras and the Early Pythagoreans OUP Oxford ISBN 978 0 19 928931 8 A history of mechanics Rene Dugas 1988 p 19 ISBN 0 486 65632 2 a b A Tiny Taste of the History of Mechanics The University of Texas at Austin Espinoza Fernando 2005 An analysis of the historical development of ideas about motion and its implications for teaching Physics Education 40 2 141 Bibcode 2005PhyEd 40 139E doi 10 1088 0031 9120 40 2 002 S2CID 250809354 Seyyed Hossein Nasr amp Mehdi Amin Razavi 1996 The Islamic intellectual tradition in Persia Routledge p 72 ISBN 978 0 7007 0314 2 Aydin Sayili 1987 Ibn Sina and Buridan on the Motion of the Projectile Annals of the New York Academy of Sciences 500 1 477 482 Bibcode 1987NYASA 500 477S doi 10 1111 j 1749 6632 1987 tb37219 x S2CID 84784804 Espinoza Fernando An Analysis of the Historical Development of Ideas About Motion and its Implications for Teaching Physics Education Vol 40 2 Pines Shlomo 1970 Abu l Barakat al Baghdadi Hibat Allah Dictionary of Scientific Biography Vol 1 New York Charles Scribner s Sons pp 26 28 ISBN 0 684 10114 9 cf Abel B Franco October 2003 Avempace Projectile Motion and Impetus Theory Journal of the History of Ideas 64 4 p 521 546 528 Sayili Aydin Ibn Sina and Buridan on the Motion the Projectile Annals of the New York Academy of Sciences vol 500 1 p 477 482 Gutman Oliver 2003 Pseudo Avicenna Liber Celi Et Mundi A Critical Edition Brill Publishers p 193 ISBN 90 04 13228 7 Hill Donald Routledge 1996 A History of Engineering in Classical and Medieval Times London Routledge p 143 ISBN 0 415 15291 7 Walter Lewin October 4 1999 Work Energy and Universal Gravitation MIT Course 8 01 Classical Mechanics Lecture 11 ogg videotape Cambridge MA US MIT OCW Event occurs at 1 21 10 10 Retrieved December 23 2010 Landau L Lifshitz E January 15 1980 The Classical Theory of Fields 4th Revised English ed Butterworth Heinemann p 27 Weinberg S May 1 2005 The Quantum Theory of Fields Volume 1 Foundations 1st ed Cambridge University Press p xxi ISBN 0521670535 Further reading EditRobert Stawell Ball 1871 Experimental Mechanics from Google books Landau L D Lifshitz E M 1972 Mechanics and Electrodynamics Vol 1 Franklin Book Company Inc ISBN 978 0 08 016739 8 External links Edit Look up mechanics in Wiktionary the free dictionary iMechanica the web of mechanics and mechanicians Mechanics Definition Mechanics Blog by a Purdue University Professor The Mechanics program at Virginia Tech Physclips Mechanics with animations and video clips from the University of New South Wales U S National Committee on Theoretical and Applied Mechanics Interactive learning resources for teaching Mechanics The Archimedes Project Retrieved from https en wikipedia org w index php title Mechanics amp oldid 1147413575, wikipedia, wiki, book, books, library,

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