Back 馬克士威方程組的歷史 Chinese

History of Maxwell's equations

For current versions of Maxwell's equations, see Maxwell's equations.
Articles about
Electromagnetism
Solenoid
Electrostatics
Magnetostatics
Electrodynamics
Electrical network
Magnetic circuit
Covariant formulation
Scientists
James Clerk Maxwell

By the first half of the 19th century, the understanding of electromagnetics had improved through many experiments and theoretical work. In the 1780s, Charles-Augustin de Coulomb established his law of electrostatics. In 1825, André-Marie Ampère published his force law. In 1831, Michael Faraday discovered electromagnetic induction through his experiments, and proposed lines of forces to describe it. In 1834, Emil Lenz solved the problem of the direction of the induction, and Franz Ernst Neumann wrote down the equation to calculate the induced force by change of magnetic flux. However, these experimental results and rules were not well organized and sometimes confusing to scientists. A comprehensive summary of the electrodynamic principles was needed.

This work was done by James C. Maxwell through a series of papers published from the 1850s to the 1870s. In the 1850s, Maxwell was working at the University of Cambridge where he was impressed by Faraday's lines of forces concept. Faraday created this concept by impression of Roger Boscovich, a physicist that impacted Maxwell's work as well.[1] In 1856, he published his 1st paper in electromagnetism: On Faraday's Lines of Force.[2] He tried to use the analogy of incompressible fluid flow to model the magnetic lines of forces. Later, Maxwell moved to King's College London where he actually came into regular contact with Faraday, and became life-long friends. From 1861 to 1862, Maxwell published a series of 4 papers under the title of On Physical Lines of Force.[3][4][5][6][7] In these papers, he used mechanical models, such as rotating vortex tubes, to model the electromagnetic field. He also modeled the vacuum as a kind of insulating elastic medium to account for the stress of the magnetic lines of force given by Faraday. These works had already laid the basis of the formulation of the Maxwell's equations. Moreover, the 1862 paper already derived the speed of light c from the expression of the velocity of the electromagnetic wave in relation to the vacuum constants. The final form of Maxwell's equations was published in 1865 A Dynamical Theory of the Electromagnetic Field, [8] in which the theory is formulated in strictly mathematical form. In 1873, Maxwell published A Treatise on Electricity and Magnetism as a summary of his work on electromagnetism. In summary, Maxwell's equations successfully unified theories of light and electromagnetism, which is one of the great unifications in physics.[9]

Maxwell built a simple flywheel model of electromagnetism, and Boltzmann built an elaborate mechanical model ("Bicykel") based on Maxwell's flywheel model, which he used for lecture demonstrations.[10] Figures are at the end of.[11]

Maxwell's differential gear model for induction. Flywheels P and Q represent the primary and secondary circuits. An increase of the moment of inertia of the flywheel in the middle illustrates the effect of placing an iron core between the two circuits.[12]

Later, Oliver Heaviside studied Maxwell's A Treatise on Electricity and Magnetism and employed vector calculus to synthesize Maxwell's over 20 equations into the 4 recognizable ones which modern physicists use. Maxwell's equations also inspired Albert Einstein in developing the theory of special relativity.[13]

The experimental proof of Maxwell's equations was demonstrated by Heinrich Hertz in a series of experiments in the 1890s.[14] After that, Maxwell's equations were fully accepted by scientists.

  1. ^ Poljak, Dragan; Sokolić, Franjo; Jakić, Mirko (2011). "Znanstveno-filozofski aspekti Boškovićeva djela i utjecaj na razvoj klasične i moderne fizike". Metodički ogledi: časopis za filozofiju odgoja (in Croatian). 18 (1): 11–34. ISSN 0353-765X.
  2. ^ Maxwell, James C. (1855–1856). "On Faraday's Lines of Force". Cambridge Philosophical Society Transactions: 27–83.
  3. ^ Maxwell, James C. (1861). On Physical Lines of Force  – via Wikisource.
  4. ^ Maxwell, James C. (1861). "On physical lines of force. Part 1. The theory of molecular vortices applied to magnetic phenomena". Philosophical Magazine. XXI: 161–175.
  5. ^ Maxwell, James C. (1861). "On physical lines of force. Part 2. The theory of electrical vortices applied to electric currents". Philosophical Magazine. XXI: 281–291.
  6. ^ Maxwell, James C. (1862). "On physical lines of force. Part 3. The theory of electrical vortices applied to statical electricity". Philosophical Magazine. XXIII: 12–24.
  7. ^ Maxwell, James C. (1862). "On physical lines of force. Part 4. The theory of electrical vortices applied to the action of magnetism on polarized light". Philosophical Magazine. XXIII: 85–95.
  8. ^ Maxwell, James C. (1865). "A dynamical theory of the electromagnetic field". Philosophical Transactions of the Royal Society of London. 155: 459–512. doi:10.1098/rstl.1865.0008. S2CID 186207827.
  9. ^ Feynman, Richard. "Chapter 18". The Feynman Lectures on Physics. Vol. II.
  10. ^ Lazaroff-Puck, Cameron (September 2015). "Gearing up for Lagrangian dynamics: The flywheel analogy in Maxwell's 1865 paper on electrodynamics". Archive for History of Exact Sciences. 69 (5): 455–490. doi:10.1007/s00407-015-0157-9. ISSN 0003-9519.
  11. ^ Boltzmann, Ludwig (1891). Ableitung der Grundgleichungen für ruhende, homogene, isotrope Körper (in German). Johann Ambrosius Barth.
  12. ^ Mayr, Otto (1971). "Maxwell and the Origins of Cybernetics". Isis. 62 (4): 425–444. ISSN 0021-1753.
  13. ^ "James Clerk Maxwell". Famous Scientists (famousscientists.org). 1 July 2014. Retrieved 2020-02-17.
  14. ^ Hertz, Heinrich (1893). Electric waves. New York, NY: Macmillan.

Developed by StudentB