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- . Abstract: The golden ratio is found to be related to the fine-structure constant, which determines the strength of the electromagnetic interaction. The golden ratio and classical harmonic proportions with quartic equations give an approximate value for the inverse fine-structure constant the same as that discovered previously in the geometry of the hydrogen atom. With…
- The fine-structure constant, which determines the strength of the electromagnetic interaction, is briefly reviewed beginning with its introduction by Arnold Sommerfeld and also includes the interest of Wolfgang Pauli, Paul Dirac, Richard Feynman and others. Sommerfeld was very much a Pythagorean and sometimes compared to Johannes Kepler. The archetypal Pythagorean triangle has long been known as a hiding place for the golden ratio. More recently, the quartic polynomial has also been found as a hiding place for the golden ratio. The Kepler triangle, with its golden ratio proportions, is also a Pythagorean triangle. Combining classical harmonic proportions derived from Kepler’s triangle with quartic equations determine an approximate value for the fine-structure constant that is the same as that found in our previous work with the golden ratio geometry of the hydrogen atom. These results make further progress toward an understanding of the golden ratio as the basis for the fine-structure constant.
- Published version: Journal of Advances in Physics, 14, 3, 5758-64 (2018).
- Search: Michael A. Sherbon fine-structure constant
- After a brief review of the golden ratio in history and our previous exposition of the fine-structure constant and equations with the exponential function, the fine-structure constant is studied …
- Michael A. Sherbon's Amazon review "The Archteypal Quest" of Arthur I Miller's Deciphering the Cosmic Number - the fine-structure constant.
- . After a brief review of the golden ratio in history and our previous exposition of the fine-structure constant and equations with the exponential function, the fine-structure constant is studied in the context of other research calculating the fine-structure constant from the golden ratio geometry of the hydrogen atom. This research is extended and the…
- Proportiones Perfectus Law is introduced by Lovemore Mamombe
- We introduce a “structure” of epic proportions – golden pyramid whose sacred geometry is “Fibonacci squared”. In terms of mathematical beauty, the golden pyramid will perhaps be found to be comparable to Pascal triangle.
- Euler's constant, Fine-structure constant, Fundamental constants, Kepler's equation
- From the exponential function of Euler's equation to the geometry of a fundamental form, a calculation of the fine-structure constant and its relationship to the proton-electron mass ratio is given. Equations are found for the fundamental constants of the four forces of nature: electromagnetism, the weak force, the strong force and the force of gravitation.…
- Quotes have been tagged as fine-structure-constant:
- From the exponential function of Euler's equation to the geometry of a fundamental form, a calculation of the fine-structure constant and its relationship to the proton-electron mass ratio is given. Equations are found for the fundamental constants of the four forces of nature: electromagnetism, the weak force, the strong force and the force of gravitation. Symmetry principles are then associated with traditional physical measures.
- Paperity: the 1st multidisciplinary aggregator of Open Access journals & papers. Free fulltext PDF articles from hundreds of disciplines, all in one place
- Michael Sherbon's Page on The Research Cooperative
publications (hide)30
- JOURNAL OF ADVANCES IN PHYSICS, 16 (1): 362--368 (October 2019)
- online, (August 2019)
- International Journal of Physical Research, 5 (2): 46-48 (2017)
- Global Journal of Science Frontier Research: A Physics and Space Science, 15 (4): 23-26 (September 2015)
- (2015)
- Helvetica Chimica Acta, 96 (12): 2304-2317 (2013-12-01T00:00:00)
- International Journal of Physical Research, 2 (1): 1-9 (March 2014)
- (2007)cite arxiv:math/0701069Comment: 22 pages, LaTeX2e; submitted to Adv. Theor. Math. Phys.
- Journal of Science, Vol. 2, No. 3, pp.148-154 (2012), (2012)
- SSRN Classics: Journal of Philosophical & Scientific Texts, (2011)
- Journal of Physics G: Nuclear and Particle Physics, 38 (4): 043201 (2011)
- SSRN Classics: Journal of Philosophical & Scientific Texts, (2010)
- (2010)cite arxiv:1004.4238 Comment: 24 pages, LaTeX.
- (2010)cite arxiv:1004.3023 Comment: 35 pages, 4 figures.
- (2009)cite arxiv:0910.4333 Comment: 39 pages, 11 pages of references. Submitted to Annalen der Physik.
- (2008)cite arxiv:0810.0752 Comment: 7 pages, no figures. Some further references added.
- (2009)cite arxiv:0902.2600.
- (2008)SSRN Classics: Journal of Philosophical & Scientific Texts.
- (2009)cite arxiv:0904.1663 Comment: 23 pages, 10 figures, The ISSI Workshop, 6-10 October 2008, on The Nature of Gravity "Confronting Theory and Experiment in Space".
- (2008)cite arxiv:0812.0713 Comment: 11 pages, 2 figures.
