Journals A-Z
All Subjects
Free Journals
sciepub.com
International Journal of Physics
ISSN (Print): 2333-4568 ISSN (Online): 2333-4576 Website: https://www.sciepub.com/journal/ijp Editor-in-chief: B.D. Indu
Open Access
Journal Browser
Go
Issue 2, Volume 11
Article Metrics
  • 3246
    Views
  • 3662
    Saves
  • 0
    Citations
  • 1
    Likes
Export Article
International Journal of Physics. 2023, 11(2), 73-80
DOI: 10.12691/ijp-11-2-3
Open AccessArticle

Experiment to Prove the Existence of the Advanced Wave and Experiment to Prove the Wrong Definition of Magnetic Field in Maxwell’s Theory

Shuang-ren Zhao1,

1Mutualenergy.org, London, Canada

Pub. Date: April 07, 2023
View Full Text Full Text PDF (342 KB) Full Text ePUB(422 KB)

Cite this paper:
Shuang-ren Zhao. Experiment to Prove the Existence of the Advanced Wave and Experiment to Prove the Wrong Definition of Magnetic Field in Maxwell’s Theory. International Journal of Physics. 2023; 11(2):73-80. doi: 10.12691/ijp-11-2-3

Abstract

Experiments were proposed using classical methods to generate advanced waves and send signals from the current to the past. The experimental methods are to change the impedance of the load and then measure the change in the output power of the power supply. According to the mutual energy theorem, the load will absorb energy from the power supply through advanced waves or advanced potentials, and the change in power supply should occur before the load changes. Therefore, it is possible to send the signal to the past. Communication from current time to the past time should be possible. This article will use three experiments to test it. These experiments are classic experiments that do not use quantum entanglement effects. This article also introduces the magnetic field measurement method using the Hall effect to measure the magnetic field of electromagnetic waves. According to the author's electromagnetic theory: mutual energy theory, the magnetic and electric fields of electromagnetic waves have a phase difference of 90 degrees. According to Maxwell's electromagnetic theory, the phase of the magnetic field and electric field is 0 degrees. The correctness of the two theories can be judged by Hall effect magnetic field measuring instruments. However, measuring instruments with high sensitivity and corresponding high frequency are required. If the phase difference between the magnetic field and electric field of an electromagnetic wave is 90 degrees, it indicates that the author's electromagnetic theory is correct, which can indirectly prove the existence of advanced waves.

Keywords:
advanced wave advanced potential Maxwell Poynting magnetic field electromagnetic field absorber theory transactional interpretation energy conservation law mutual energy flow antenna transformer

Creative CommonsThis work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

References:

[1]  J. A. Wheeler and R. P. Feynman, “Interaction with the absorber as the mechanism of radiation,” Rev. Mod. Phys., vol. 17, p. 157, April 1945.
 
[2]  J. A. Wheeler and R. P. Feynman, “Classical electrodynamics in terms of direct interparticle action,” Rev. Mod. Phys., vol. 21, p. 425, July 1949.
 
[3]  J. Cramer, “The transactional interpretation of quantum mechanics,” Reviews of Modern Physics, vol. 58, pp. 647-688, 1986.
 
[4]  J. Cramer, “An overview of the transactional interpretation,” International Journal of Theoretical Physics, vol. 27, p. 227, 1988.
 
[5]  J. Cramer, “The transactional interpretation of quantum mechanics and quantum nonlocality,” https://arxiv.org/abs/1503.00039, 2015.
 
[6]  Mathematical Foundations of Quantum Theory, edited by A.R. Marlow, Academic Press, 1978. P, 39 lists seven experiments: double slit, microscope, split beam, tilt-teeth, radiation pattern, one-photon polarization, and polarization of paired photons.
 
[7]  Walborn, S. P.; et al. (2002). "Double-Slit Quantum Eraser”. Phys. Rev. A. 65 (3): 033818. arXiv:quant-ph/0106078Freely accessible. Bibcode:2002PhRvA..65c3818W.
 
[8]  Yaron Bromberg, Ori Katz, Yaron Silberberg, Ghost imaging with a single detector, https://arxiv.org/abs/0812.2633, 2008.
 
[9]  John G. Cramer, Nick Herbert, An Inquiry into the Possibility of Nonlocal Quantum Communication, arXiv:1409.5098, 2015.
 
[10]  W. J. Welch, “Reciprocity theorems for electromagnetic fields whose time dependence is arbitrary,” IRE trans. On Antennas and Propagation, vol. 8, no. 1, pp. 6-73, January 1960.
 
[11]  S. ren Zhao, “The application of mutual energy theorem in expansion of radiation fields in spherical waves,” ACTA Electronica Sinica, P.R. of China, vol. 15, no. 3, pp. 88-93, 1987.
 
[12]  S. Zhao, “The simplification of formulas of electromagnetic fields by using mutual energy formula,” Journal of Electronics, P.R. of China, vol. 11, no. 1, pp. 73-77, January 1989.
 
[13]  S. Zhao, “The application of mutual energy formula in expansion of plane waves,” Journal of Electronics, P. R. China, vol. 11, no. 2, pp. 204-208, March 1989.
 
[14]  S. ren Zhao, K. Yang, K. Yang, X. Yang, and X. Yang. (2015) The modified poynting theorem and the concept of mutual energy. [Online]. Available: http://arxiv.org/abs/1503.02006.
 
[15]  Shuang-ren Zhao, Kevin Yang, Kang Yang, Xingang Yang, Xintie Yang, The principle of the mutual energy, arXiv:1606.08710, 2016.
 
[16]  Shuang-ren Zhao, Kevin Yang, Kang Yang, Xingang Yang, Xintie Yang, The mutual energy current interpretation for quantum mechanics, arXiv:1608.08055, 2016.
 
[17]  W. Ritz, “Recherches critiques sur l’electrodynamique generale,” Annales de Chimie et de Physique, vol. 13, pp. 145-275, 1908.
 
[18]  W. Ritz, “Recherches critiques sur les theories electrodynamiques de cl. maxwell et de h.-a. lorentz,” Archives des Sciences physiques et naturelles, vol. 36, p. 209, 1908.
 
[19]  Shuang ren Zhao. A new interpretation of quantum physics: Mutual energy flow interpretation. American Journal of Modern Physics and Application, 4(3): 12-23, 2017.
 
[20]  Shuang-ren Zhao, Photon Can Be Described as the Normalized Mutual Energy Flow. Journal of Modern Physics Vol.11 No.5, May 202. https://www.scirp.org/journal/paperinformation.aspx?paperid=100036.
 
[21]  Shuang-ren Zhao, A solution for wave-particle duality using the mutual energy principle corresponding to Schrödinger equation, https://hal.science/hal-02270483v1.
 
[22]  Shuang-ren Zhao, Huygens principle based on mutual energy flow theorem and the comparison to the path integral, Physics Tomorrow Letter, November, 2020. https://hal.science/hal-02270471.
 
[23]  shuang-ren Zhao, Solve the Maxwell's equations and Schrodinger's equation but avoiding the Sommerfeld radiation condition, Theoretical Physics Letters 2022 ° 26(04) ° 10-05.
 
[24]  Shuang-ren Zhao. Mutual stress flow theorem of electromagnetic field and extension of newton's third law. Theoretical Physics Letters, 10(7), 2022. https://hal.science/hal-03221429v1.
 
[25]  Shuang ren Zhao. The paradox that induced electric field has energy in Maxwell theory of classical electromagnetic field is shown and solved. International Journal of Physics, 10(4): 204-217, 2022.
 
[26]  Shuang ren Zhao. The theory of mutual energy flow proves that macro-scopic electromagnetic waves are composed of photons. International Journal of Physics, 10(5), 2022. http://article.internationaljournalofphysics.com/pdf/ijp-10-4-4.pdf.
 
[27]  Shuang-ren Zhao, The Contradictions in Poynting Theorem and Classical Electromagnetic Field Theory, International Journal of Physics, 2022, Vol. 10, No. 5, 242-251.
 
[28]  Shuang-ren Zhao, Energy Flow and Photons from Primary Coil to Secondary Coil of Transformer, International Journal of Physics. 2023, 11(1), 24-39.
 
[29]  Shuang-ren Zhao Energy Conservation Law and Energy Flow Theorem for Transformer, Antenna and Photon International Journal of Physics. 2023, 11(2), 56-66.
 
Manuscript template