Indexing
All Issues
Submission
Author Guidelines
Reviewers
Editorial Members
Publication Fee
Vol.1 , No. 3, Publication Date: Jun. 19, 2015, Page: 206-221
| [1] | F. F. Mende, B. Verkin Institute for Low Temperature Physics and Engineering NAS Ukraine, Kharkov, Ukraine. |
| [2] | A. V. Kukushkin, Department of Computational Systems and Technologies, R. Alekseev Nizhny Novgorod State Technical University, Nizhny Novgorod, Russia. |
| [3] | A. A. Rukhadze, A. Prokhorov General Physics Institute of the Russian Academy, Moscow, Russia. |
The fundamental equations of contemporary classical electrodynamics are Maxwell's equations. But not all know that those equations, which it is customary to assume as Maxwell's equations, not are those equations, which used itself Maxwell. During writing of its equations it used the substantional derivative, that are made themselves they invariant with respect to the conversions of Galileo. Subsequently Hertz and Heaviside excluded from the substantional derivative its convective part, after writing down Maxwell's equations in the partial derivatives. In the article are examined the conversions of electromagnetic pour on upon transfer of one inertial system to another, obtained on the basis of the equations of electromagnetic and magnetoelectric induction with the use by the substantional derivative and they are examined the consequences, which escape from such conversions. Physics of the emission of electromagnetic waves on the basis of the concept of scalar-vector potential is examined and shown that this concept assumes the clear separation between the gradient and vorticity fields. Are discussed the problems, which appear in the theory of electromagnetism because of the delivery here of the principles of relativistic mechanics for describing the motion of energy of free waves carried out in the article. It is shown that this delivery leads to the sufficiently rigid kinematic censorship. Thus, examined in the article for an example normal H_n0 is waves hollow rectangular waveguide this censorship do not pass. Are discussed questions and consequences for the theories, connected with this fact.
Keywords
Maxwell's Equation, Substantional Derivative, Electromagnetic Induction, Magnetoelectric Induction, Kinetic Wave Energy, Rest Energy of Wave, Speed of Wave Energy
Reference
| [01] | James Clerk Maxwell. Selected works on the theory of the electric field, the State publishing technical and theoretical literature, Moscow, 1954. |
| [02] | Heinrich Hertz. Electric force, St. Petersburg, 1894. |
| [03] | O. Heaviside. Electrical Papers. London, 1892. |
| [04] | A. V. Kukushkin, A. A. Rukhadze. Relativistic covariant theory of electromagnetic waves energy transfer, Engineering physics, 2014, № 5, pp. 18-52. |
| [05] | W. Pauli. Theory of relativity, M, Science, 1983. |
| [06] | L. D. Landau, E. M. Lifshits. Electrodynamics of continuous media, M, .Science, 1973. |
| [07] | G. Beytmen. Mathematical theory of the propagation of the electromagnetic waves, M, . GIFML, 1958. |
| [08] | J. H. Poynting, On the Transfer of Energy in the Electromagnetic Field, Phil. Trans. Roy. Soc. London 175, 343, 1884. |
| [09] | N. A. Umov. Equations of motion are energy in the bodies, Odessa: Ulrich and Schulz, 1874. |
| [10] | L. A. Weinstein. Electromagnetic waves, M.: Radios and connection, 1988. |
| [11] | L. I. Mandelshtam. Lecture on optics, SR and to quantum mechanics, M.: Science, 1972. |
| [12] | A.V. Kukushkin. Mathematical Basis of Transverse Plane Waves Theory. Wave Particles of the Class ical Field, Applied physics and mathematics, №1, 2013, pp. 98-119. |
| [13] | P. K. Rashevskii. Riemann geometry and tensor analysis. M : Nauka, 1967. |
| [14] | F. F. Mende. On refinement of equations of electromagnetic induction, – Kharkov, deposited in VINITI, No 774 – B88 Dep., 1988. |
| [15] | F. F. Mende. Experimental corroboration and theoretical interpretation of dependence of charge value on DC flow velocity through superconductors. Proceedings International Conference “Physics in Ukraine”, Kiev, 1993. |
| [16] | F. F. Mende. Are there errors in modern physics. Kharkov, Constant, 2003. |
| [17] | F. F. Mende Consistent electrodynamics and the threat of nuclear Space terrorism. Kharkov NTMT, 2008. |
| [18] | F. F. Mende. Great misconceptions and errors physicists XIX-XX centuries. Revolution in modern physics, Kharkоv, NTMT, 2010. |
| [19] | F. F. Mende. New electrodynamics. Revolution in the modern physics. Kharkov, NTMT, 2012. |
| [20] | R. Feynman, R. Leighton, M. Sends. Feynman lectures on physics, М: Mir, Vol. 6, 1977. |
