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Alileche, Abdelkrim

Newton and the Big Bang

Further Mathematical Exploration of Newton’s Gravity Law and Coulomb’s Electrostatic Law

A Theoretical Assay on the Quantization of the Waves of Electromagnetic Waves Based on Logarithmic Analysis

A Theoretical Assay on the similarity of Light Refraction in a medium and the Compton Effect

Abstract Views :106 | PDF Views:0

Authors

Abdelkrim Alileche ¹

Affiliations
1 Boise State University, Biology Department,1910, University Drive Boise ID 83725, US

Source

Journal of Physics & Astronomy, Vol 10, No 9 (2022), Pagination: 1-5

Abstract

A further mathematical analysis of electromagnetic waves (EMWs) laws, namely the Planck law E=hv and an authorless law λv=c, reveals several issues in the interpretation of EMW refraction in a medium like glass, water etc. According to the current opinion, upon refraction EMWs keep their frequency before refraction. Such an interpretation overlooks many aspects of EMWs, and I am challenging it by stating that upon refraction the frequency of an EMW cannot stay as it was, it diminishes, and its wavelength becomes larger. This new opinion shows the similarity of EMWs refraction and the Compton effect and opens to new developments in physics such as new types of computers depending not on moving electrons but EMWs.

Keywords

Electromagnetic waves, Refraction .

Full Text

References

Alileche A (2022). A theoretical assay on the quantization of the waves of electromagnetic waves based on logarithmic analysis. J. Phys. Astron;10(9):1-3

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Krysac LC, editor (2006). Sound and Electromagnetic Waves: An Anthology of Current Thought. An Anthology of Current Thought ISBN 1-4042-0407-5, page 105

A New Interpretation of Thomas Young Refractive Index Law n=c/v

Abstract Views :77 | PDF Views:0

Authors

Abdelkrim Alileche ¹

Affiliations
1 Boise State University, Biology Department, 1910 University Drive, Boise ID 83725, USA., US

Source

Journal of Physics & Astronomy, Vol 11, No 3 (2023), Pagination: 01-03

Abstract

The Thomas Young refraction law established in 1807 needs a new evaluation. So far this law, simple in its formulation n=v/c, has been applied only when light passes from low refractive index medium like air to a high refractive index medium like glass and never when light exits back to air. New developments like the slowing down of light up to 17 ms ^-1 by Lene Hau and others, and the widespread use of optic fibers to transmit a huge amount of all kind of information and the Internet around the world, mandates the new evaluation. The matter at hand is whether we apply this law when light exits from glass to air, or we need a new formulation of the Thomas Young law for its new application.

Keywords

Young Law, Refractive Index Medium.

Full Text

References

Young T. A course of lectures on natural philosophy and the mechanical arts: in two volumes. Johnson; 1807.

Alileche A. A Theoretical Assay on the similarity of Light Refraction in a medium and the Compton Effect J. Phys. Astron.2022;10(9):296

Alileche A. Theoretical Assay on the Quantization of the Waves of Electromagnetic Waves Based on Logarithmic Analysis J. Phys. Astron.2022;10(9):295

Maxwell JC. VIII. A dynamical theory of the electromagnetic field. Philos. trans. R. Soc. Lond.1865(155):459-512.

Hau LV, Harris SE, Dutton Z, et al. Light speed reduction to 17 metres per second in an ultracold atomic gas. Nature. 1999;397(6720):594-8.

Liu C, Dutton Z, Behroozi CH, et al. Observation of coherent optical information storage in an atomic medium using halted light pulses. Nature. 2001;409(6819):490-3.

Kash MM, Sautenkov VA, Zibrov AS, et al. Ultraslow group velocity and enhanced nonlinear optical effects in a coherently driven hot atomic gas. Phys. Rev. Lett. 1999;82(26):5229.

Brehm JD, Gebauer R, Stehli A, et al. Slowing down light in a qubit metamaterial. Appl. Phys. Lett. 2022;121(20):204001.

Bons PC, De Haas R, De Jong D, et al. Quantum enhancement of the index of refraction in a Bose-Einstein condensate. Phys. rev. lett. 2016;116(17):173602.

Alileche A. Lorentz contraction of the frequency of electromagnetic waves (EMWs) during refraction submitted to J. Phys. Astron.2023;11(3):326

Alileche A.A theoretical assay on the similarity of light refraction in a medium and the Compton effect J. Phys. Astron. 2022;10(9):296

Lorentz contraction of the Frequency of Electromagnetic Waves (EMWs) during Refraction

Abstract Views :60 | PDF Views:0

Authors

Abdelkrim Alileche ¹

Affiliations
1 Boise State University, Biology Department, 1910 University Drive, Boise ID 83725, USA., US

Source

Journal of Physics & Astronomy, Vol 11, No 3 (2023), Pagination: 01-03

Abstract

The design of computers running not on moving electrons but on EMWs needs a serious review of our knowledge and theories about the behavior of EMWs upon refraction. The fact light can be slowed to 17 ms^-1 is a serious challenge to Einstein special relativity, a theory based on the constant speed of light for all inertial frames. This study brings a new version of the Lorentz factor this time applied to only moving EMWs in condensed medium. For the first time quantum mechanics and special relativity are together in a new formulation of Planck energy law E=hν.

Keywords

Quantum Mechanics, Moving electrons.

Full Text

References

Einstein A. On the electrodynamics of moving bodies. Annalen der physik. 1905;17(10):891-921.

Mc Mahon D.Relativity demystified, A self-teaching guide ISBN 0-07-145545-0.2006:9

Aczel AD. Pendulum: Leon Foucault and the triumph of science. 1st Atria. Atria, New York. 2003.

Hau LV, Harris SE, Dutton Z, et al. Light speed reduction to 17 metres per second in an ultracold atomic gas. Nature. 1999;397(6720):594-8.

Liu C, Dutton Z, Behroozi CH, et al. Observation of coherent optical information storage in an atomic medium using halted light pulses. Nature. 2001;409(6819):490-3.

Kash MM, Sautenkov VA, Zibrov AS, et al. Ultraslow group velocity and enhanced nonlinear optical effects in a coherently driven hot atomic gas. Phys. Rev. Lett. 1999;82(26):5229.

Brehm JD, Gebauer R, Stehli A, et al. Slowing down light in a qubit metamaterial. Phys. Rev. Lett. 2022;121(20):204001.

Bons PC, De Haas R, De Jong D, et al. Quantum enhancement of the index of refraction in a Bose-Einstein condensate. Phys. Rev. Lett. 2016;116(17):173602.

Chen H, Sha WE, Dai X, et al. On The Low Speed Limits of Lorentz's Transformation. arXiv preprint arXiv:2202.10242. 2022.

Alileche A. A theoretical assay on the quantization of the waves of electromagnetic waves based on logarithmic analysis. J. Phys. Astron.2022;10(9);95

Alileche A.A theoretical assay on the similarity of light refraction in a medium and the Compton Effect. J. Phys. Astron.2022;10(9):96

Alileche A.A new interpretation of the refraction index of an electromagnetic wave n = c/v Submitted to Journal of Physics and Astronomy. J. Phys. Astron.2023;11(3).

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