History of classical mechanics

In physics mechanics is the study of objects their interaction and motion classical mechanics is mechanics limited to non relativistic and non quantum approximations Most of the techniques of classical mechanics were developed before 1900 so the term classical mechanics refers to that historical era as well as the approximations Other fields of physics that were developed in the same era that use the same approximations and are also considered classical include thermodynamics see history of thermodynamics and electromagnetism see history of electromagnetism The critical historical event in classical mechanics was the publication by Isaac Newton of his laws of motion and his associated development of the mathematical techniques of calculus in 1678 Analytic tools of mechanics grew through the next two centuries including the development of Hamiltonian mechanics and the action principles concepts critical to the development of quantum mechanics and of relativity Chaos theory is a subfield of classical mechanics that was developed in its modern form in the 20th century Precursors to Newtonian mechanicsAntiquity Aristotle s laws of motion In Physics he states that objects fall at a speed proportional to their weight and inversely proportional to the density of the fluid they are immersed in This is a correct approximation for objects in Earth s gravitational field moving in air or water The ancient Greek philosophers Aristotle in particular were among the first to propose that abstract principles govern nature Aristotle argued in On the Heavens that terrestrial bodies rise or fall to their natural place and stated as a law the correct approximation that an object s speed of fall is proportional to its weight and inversely proportional to the density of the fluid it is falling through Aristotle believed in logic and observation but it would be more than eighteen hundred years before Francis Bacon would first develop the scientific method of experimentation which he called a vexation of nature Aristotle saw a distinction between natural motion and forced motion and he believed that in a void i e vacuum a body at rest will remain at rest and a body in motion will continue to have the same motion In this way Aristotle was the first to approach something similar to the law of inertia However he believed a vacuum would be impossible because the surrounding air would rush in to fill it immediately He also believed that an object would stop moving in an unnatural direction once the applied forces were removed Later Aristotelians developed an elaborate explanation for why an arrow continues to fly through the air after it has left the bow proposing that an arrow creates a vacuum in its wake into which air rushes pushing it from behind Aristotle s beliefs were influenced by Plato s teachings on the perfection of the circular uniform motions of the heavens As a result he conceived of a natural order in which the motions of the heavens were necessarily perfect in contrast to the terrestrial world of changing elements where individuals come to be and pass away There is another tradition that goes back to the ancient Greeks where mathematics is used to analyze bodies at rest or in motion which may found as early as the work of some Pythagoreans Other examples of this tradition include Euclid On the Balance Archimedes On the Equilibrium of Planes On Floating Bodies and Hero Mechanica Later Islamic and Byzantine scholars built on these works and these ultimately were reintroduced or became available to the West in the 12th century and again during the Renaissance Medieval thought 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 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 projectile in a vacuum would not stop unless it is acted upon This conception of motion is consistent with Newton s first law of motion inertia Which states that an object in motion will stay in motion unless it is acted on by an external force In the 12th century Hibat Allah Abu l Barakat al Baghdaadi adopted and modified Avicenna s theory on projectile motion In his Kitab al Mu tabar Abu l Barakat stated that the mover imparts a violent inclination mayl qasri on the moved and that this diminishes as the moving object distances itself from the mover 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 In the 14th century French priest Jean Buridan developed the theory of impetus with possible influence by Ibn Sina Albert Bishop of Halberstadt developed the theory further Nicole Oresme one of Oxford Calculators at Merton College Oxford provided the mean speed theorem using geometrical arguments Renaissance Table of Mechanicks from the 1728 Cyclopaedia Galileo Galilei s development of the telescope and his observations further challenged the idea that the heavens were made from a perfect unchanging substance Adopting Copernicus s heliocentric hypothesis Galileo believed the Earth was the same as other planets Though the reality of the famous Tower of Pisa experiment is disputed he did carry out quantitative experiments by rolling balls on an inclined plane his correct theory of accelerated motion was apparently derived from the results of the experiments Galileo also found that a body dropped vertically hits the ground at the same time as a body projected horizontally so an Earth rotating uniformly will still have objects falling to the ground under gravity More significantly it asserted that uniform motion is indistinguishable from rest and so forms the basis of the theory of relativity Except with respect to the acceptance of Copernican astronomy Galileo s direct influence on science in the 17th century outside Italy was probably not very great Although his influence on educated laymen both in Italy and abroad was considerable among university professors except for a few who were his own pupils it was negligible Christiaan Huygens was the foremost mathematician and physicist in Western Europe He formulated the conservation law for elastic collisions produced the first theorems of centripetal force and developed the dynamical theory of oscillating systems He also made improvements to the telescope discovered Saturn s moon Titan and invented the pendulum clock Newtonian mechanicsIsaac Newton was the first to unify the three laws of motion the law of inertia his second law mentioned above and the law of action and reaction and to prove that these laws govern both earthly and celestial objects Newton and most of his contemporaries hoped that classical mechanics would be able to explain all entities including in the form of geometric optics light Newton s own explanation of Newton s rings avoided wave principles and supposed that the light particles were altered or excited by the glass and resonated Newton also developed the calculus which is necessary to perform the mathematical calculations involved in classical mechanics However it was Gottfried Leibniz who independently of Newton developed a calculus with the notation of the derivative and integral which are used to this day Classical mechanics retains Newton s dot notation for time derivatives Leonhard Euler extended Newton s laws of motion from particles to rigid bodies with two additional laws Working with solid materials under forces leads to deformations that can be quantified The idea was articulated by Euler 1727 and in 1782 Giordano Riccati began to determine elasticity of some materials followed by Thomas Young Simeon Poisson expanded study to the third dimension with the Poisson ratio Gabriel Lame drew on the study for assuring stability of structures and introduced the Lame parameters These coefficients established linear elasticity theory and started the field of continuum mechanics Classical mechanics timeline by lifetimes of key scientistsAnalytical mechanicsAfter Newton re formulations progressively allowed solutions to a far greater number of problems The first was constructed in 1788 by Joseph Louis Lagrange an Italian French mathematician In Lagrangian mechanics the solution uses the path of least action and follows the calculus of variations William Rowan Hamilton re formulated Lagrangian mechanics in 1833 resulting in Hamiltonian mechanics In addition to the solutions of important problems in classical physics these techniques form the basis for quantum mechanics Lagrangian methods evolved in to the path integral formulation and the Schrodinger equation builds Hamiltonian mechanics In the middle of the 19th century Hamilton could claim classical mechanics as at the center of attention among scholars The theoretical development of the laws of motion of bodies is a problem of such interest and importance that it has engaged the attention of all the eminent mathematicians since the invention of the dynamics as a mathematical science by Galileo and especially since the wonderful extension which was given to that science by Newton William Rowan Hamilton 1834 Transcribed in Classical Mechanics by J R Taylor 237 Origin of chaos theoryIn the 1880s while studying the three body problem Henri Poincare found that there can be orbits that are nonperiodic and yet not forever increasing nor approaching a fixed point In 1898 Jacques Hadamard published an influential study of the chaotic motion of a free particle gliding frictionlessly on a surface of constant negative curvature called Hadamard s billiards Hadamard was able to show that all trajectories are unstable in that all particle trajectories diverge exponentially from one another with a positive Lyapunov exponent These developments led in the 20th century to the development of chaos theory Conflicts at the end of the 19th centuryAlthough classical mechanics is largely compatible with other classical physics theories such as classical electrodynamics and thermodynamics some difficulties were discovered in the late 19th century that could only be resolved by modern physics When combined with classical thermodynamics classical mechanics leads to the Gibbs paradox in which entropy is not a well defined quantity As experiments reached the atomic level classical mechanics failed to explain even approximately such basic things as the energy levels and sizes of atoms The effort at resolving these problems led to the development of quantum mechanics Action at a distance was still a problem for electromagnetism and Newton s law of universal gravitation these were temporary explained using aether theories Similarly the different behaviour of classical electromagnetism and classical mechanics under velocity transformations led to the Albert Einstein s special relativity Modern physicsAt the beginning of the 20th century quantum mechanics 1900 and relativistic mechanics 1905 were discovered This development indicated that classical mechanics was just an approximation of these two theories The theory of relativity introduced by Einstein would later also include general relativity 1915 that would rewrite gravitational interactions in terms of the curvature of spacetime Relativistic mechanics recovers Newtonian mechanics and Newton s gravitational law when the speeds involved are much smaller than the speed of light and masses involved are smaller than stellar objects Quantum mechanics describing atomic and sub atomic phenomena was also updated in the 1915 to quantum field theory that would lead to the Standard Model of elementary particles and elementary interactions like electromagnetism the strong interaction and the weak interaction Quantum mechanics recovers classical mechanics at the macroscopic scale in the presence of decoherence The unification of general relativity and quantum field theory into a quantum gravity theory is still an open problem in physics Later developmentsEmmy Noether proved the Noether s theorem in 1918 relating symmetries and conservation laws it applies to all realms of physics including classical mechanics In 1954 Andrey Kolmogorov revisited the work of Poincare He considered the problem of whether or not a small perturbation of a conservative dynamical system resulted in a quasiperiodic orbit in celestial mechanics The same problem was worked by Jurgen Moser and later by Vladimir Arnold leading to the Kolmogorov Arnold Moser theorem and KAM theory Meteorologist Edward Norton Lorenz is often credited as rediscovering the field of chaos theory About 1961 he discovered that his weather calculations were sensitive to the significant figures in the initial conditions He later developed the theory of Lorenz system In 1971 David Ruelle coined the term strange attractor to describe these systems The term chaos theory was finally coined in 1975 by James A Yorke See alsoMechanics Timeline of classical mechanics History of classical field theoryNotesRovelli Carlo 2015 Aristotle s Physics A Physicist s Look Journal of the American Philosophical Association 1 1 23 40 arXiv 1312 4057 doi 10 1017 apa 2014 11 S2CID 44193681 Peter Pesic March 1999 Wrestling with Proteus Francis Bacon and the Torture of Nature Isis 90 1 The University of Chicago Press on behalf of The History of Science Society 81 94 doi 10 1086 384242 JSTOR 237475 S2CID 159818014 Aristotle On the Heavens de Caelo book 13 section 295a Aristotle Physics Book 4 On motion in a void 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 Gutman Oliver 2003 Pseudo Avicenna Liber Celi Et Mundi A Critical Edition Brill Publishers p 193 ISBN 90 04 13228 7 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 Nicholas Oresme French Bishop Economist amp Philosopher Britannica www britannica com Retrieved 2024 03 27 Palmieri Paolo 2003 06 01 Mental models in Galileo s early mathematization of nature Studies in History and Philosophy of Science Part A 34 2 229 264 Bibcode 2003SHPSA 34 229P doi 10 1016 S0039 3681 03 00025 6 ISSN 0039 3681 Galilei Galileo Complete Dictionary of Scientific Biography Retrieved April 06 2021 from Encyclopedia com https www encyclopedia com science dictionaries thesauruses pictures and press releases galilei galileo Blasjo Viktor 2021 02 12 Galileo Ignoramus Mathematics versus Philosophy in the Scientific Revolution arXiv 2102 06595 math HO Cohen H Floris 1991 How Christiaan Huygens Mathematized Nature The British Journal for the History of Science 24 1 79 84 doi 10 1017 S0007087400028466 ISSN 0007 0874 JSTOR 4027017 S2CID 122825173 Gabriel Lame 1852 Lecons sur la theorie mathematique de l elasticite des corps solides Bachelier John Robert Taylor 2005 Classical Mechanics University Science Books ISBN 978 1 891389 22 1 Poincare Jules Henri 1890 Sur le probleme des trois corps et les equations de la dynamique Divergence des series de M Lindstedt Acta Mathematica 13 1 2 1 270 doi 10 1007 BF02392506 Poincare J Henri 2017 The three body problem and the equations of dynamics Poincare s foundational work on dynamical systems theory Popp Bruce D Translator Cham Switzerland Springer International Publishing ISBN 9783319528984 OCLC 987302273 Diacu Florin Holmes Philip 1996 Celestial Encounters The Origins of Chaos and Stability Princeton University Press Hadamard Jacques 1898 Les surfaces a courbures opposees et leurs lignes geodesiques Journal de Mathematiques Pures et Appliquees 4 27 73 Emmy Noether the mathematician who changed the face of physics EP News Retrieved 2024 10 23 Oestreicher Christian 2007 09 30 A history of chaos theory Dialogues in Clinical Neuroscience 9 3 279 289 doi 10 31887 DCNS 2007 9 3 coestreicher ISSN 1958 5969 PMC 3202497 PMID 17969865 ReferencesTruesdell C 1968 Essays in the History of Mechanics Berlin Heidelberg Springer Berlin Heidelberg ISBN 9783642866470 Maddox Rene Dugas foreword by Louis de Broglie translated into English by J R 1988 A history of mechanics Dover ed New York Dover Publications ISBN 0 486 65632 2 a href wiki Template Cite book title Template Cite book cite book a CS1 maint multiple names authors list link Buchwald Jed Z Fox Robert eds 2013 The Oxford handbook of the history of physics First ed Oxford Oxford University Press pp 358 405 ISBN 9780199696253