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Classical mechanics - History | | Classical mechanics - History: Encyclopedia II - Classical mechanics - History | | Main article: History of classical mechanics
The Greeks, and Aristotle in particular, were the first to propose that there are abstract principles governing nature.
One of the first scientists who suggested abstract laws was Galileo Galilei who may have performed the famous experiment of dropping two cannon balls from the tower of Pisa. (The theory and the practice showed that they both hit the ground at the same time.) Though the reality of this experiment is disputed, he did carry out quantitative experiments by rolling balls on an inclined plane; his correct theory of accelerated motion was apparent ...
See also:Classical mechanics, Classical mechanics - Description of the theory, Classical mechanics - Position and its derivatives, Classical mechanics - Forces; Newton's second law, Classical mechanics - Energy, Classical mechanics - Beyond Newton's Laws, Classical mechanics - Classical transformations, Classical mechanics - History, Classical mechanics - Limits of validity, Classical mechanics - The classical approximation to special relativity, Classical mechanics - The classical approximation to quantum mechanics, Classical mechanics - Notes | | | Classical mechanics, Classical mechanics - Beyond Newton's Laws, Classical mechanics - Classical transformations, Classical mechanics - Description of the theory, Classical mechanics - Energy, Classical mechanics - Forces; Newton's second law, Classical mechanics - History, Classical mechanics - Limits of validity, Classical mechanics - Notes, Classical mechanics - Position and its derivatives, Classical mechanics - The classical approximation to quantum mechanics, Classical mechanics - The classical approximation to special relativity, Celestial mechanics, List of equations in classical mechanics, List of publications in classical mechanics | | |
| | | Classical mechanics: Encyclopedia II - Classical mechanics - History
Classical mechanics - History
Main article: History of classical mechanics
The Greeks, and Aristotle in particular, were the first to propose that there are abstract principles governing nature.
One of the first scientists who suggested abstract laws was Galileo Galilei who may have performed the famous experiment of dropping two cannon balls from the tower of Pisa. (The theory and the practice showed that they both hit the ground at the same time.) Though the reality of this 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.
Sir Isaac Newton was the first to propose 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 everyday objects and celestial objects.
Newton and most of his contemporaries, with the notable exception of Christiaan Huygens hoped that classical mechanics would be able to explain all entities, including (in the form of geometric optics) light. When he discovered Newton's rings, Newton's own explanation avoided wave principles and resembled more the explanation for the decay of the neutral Kaons, K0 and K0 bar. That is, he 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 developed the notation of the derivative and integral which are used to this day.
After Newton the field became more mathematical and more abstract.
Although 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 more 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. Similarly, the different behaviour of classical electromagnetism and classical mechanics under velocity transformations led to the theory of relativity.
By the end of the 20th century, the place of classical mechanics in physics is no longer that of an independent theory. Along with classical electromagnetism, it has become imbedded in relativistic quantum mechanics or quantum field theory[2]. It is the non-relativistic, non-quantum mechanical limit for massive particles.
Other related archivesAristotle, Bohr, Brahe, Celestial mechanics, Christiaan Huygens, Clinton Davisson, Einstein, Euclidean geometry, Feynman Lectures on Physics, Galilean relativity, Galilean transformation, Galileo, Galileo Galilei, Gibbs paradox, Gottfried Leibniz, Greeks, Hamiltonian mechanics, History of classical mechanics, Kaons, Kepler, Lagrangian mechanics, Leibniz, Lester Germer, List of equations in classical mechanics, List of publications in classical mechanics, Lorentz force, Maxwell's equations, Newton, Newton's law, Newton's rings, Newton's second law, Newtonian mechanics, Planck, Plank's constant, Sir Isaac Newton, Special Relativity, absolute time, acceleration, angular momentum, angular resolution, baseball, bodies, calculus, center of mass, classical physics, composite, crystal, cyclotron, de Broglie, decays exponentially, degrees of freedom, derivative, diffraction, electrodynamics, electromagnetism, electron, electrons, energy, entropy, force, forces, galaxies, gases, geometric optics, gradient, gravitational force, group transformation, gyrotron, high frequency approximation, inclined plane, integral, integrated, integrated circuit, integrated circuits, kinetic energy, liquids, machinery, magnetron, mass, mechanics, molecules, momentum, negligible, ordinary differential equation, parameters, physical laws, physics, planets, point particles, position, potential energy, projectiles, quantum field theory, quantum mechanics, quantum tunneling, rate of change, reference frames, relativistic, resistive force, rest mass, rocket, side lobe, solids, space, spacecraft, special relativity, speed of light, spin, stars, theory of relativity, thermodynamics, time, tower of Pisa, transistor, tunnel diodes, unit vectors, vacuum chamber, vector, velocity
 Adapted from the Wikipedia article "History", under the G.N U Free Docmentation License. Please also see http://en.wikipedia.org/wiki |
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