Paper Titles in Periodical
International Letters of Chemistry, Physics and Astronomy
Volume 61

Subscribe

Subscribe to our Newsletter and get informed about new publication regulary and special discounts for subscribers!

ILCPA > Volume 61 > Compton Wavelengths for the Proton and Electron...
Compton Wavelengths for the Proton and Electron May Differ by Hyperspace Geometry: Are they the same Particle Bifurcated?
< Back to Volume

Compton Wavelengths for the Proton and Electron May Differ by Hyperspace Geometry: Are they the same Particle Bifurcated?

Full Text PDF

Abstract:

The discrepancy between the Compton wavelength of a proton and an electron has been assumed to reflect some shared variable with their respective masses. However this discrepancy of 1.83·103 is remarkably similar to the geometric constant (21.3 π4) derived from the product of four dimensional space-time for closed circular boundaries. This same formulation, when the appropriate powers for Newton’s Gravitational Constant and the mass, duration, and length of the universe were multiplied, resulted in a diffusivity value that has been considered a potential entanglement velocity. This value is the same order of magnitude as the ratio of 2π multiplied by the neutral hydrogen wavelength divided by a quantum “jiffy”. The quantifications suggest that the difference between the space, as inferred by wavelength, occupied by the electron and the proton are related by the geometric structure of space-time. Their distinctions as different particles are manifested when the temporal increments of observations are much, much less than the duration of the universe.

Info:

Periodical:
International Letters of Chemistry, Physics and Astronomy (Volume 61)
Pages:
101-104
DOI:
https://doi.org/10.18052/www.scipress.com/ILCPA.61.101
Citation:
M. A. Persinger and L. S. St-Pierre, "Compton Wavelengths for the Proton and Electron May Differ by Hyperspace Geometry: Are they the same Particle Bifurcated?", International Letters of Chemistry, Physics and Astronomy, Vol. 61, pp. 101-104, 2015
Online since:
Nov 2015
Authors:
Michael A. Persinger, Linda S. St-Pierre
Keywords:
Compton Wavelength, Electron, Proton, Space-Time Geometry
Export:
RIS, BibTeX, Text
Distribution:
Open Access

Creative Commons License
This work is licensed under a
Creative Commons Attribution 4.0 International License

References:

[1] H. Weyl, Space Time Matter Dover Publications, N.Y., (1952).

[2] H. E. Puthoff, Physical Review General Physics 39 (1989) 233-2342.

[3] C. Morris, Academic Press Dictionary of Science and Technology Academic Press, San Diego, (1992).

[4] R. Pohl, A. Antognini, F. Nez, F. D. Amaro, f. Biaraben, J. M. Cardoso, et al, Nature 466 (2010) 213-216.

[5] G. Aad et al (344 authors), Physical Review Letters 114 (2015) 191803.

[6] M. A. Persinger, International Journal of Astronomy and Astrophysics 2 (2012) 125-128.

[7] A. D. Aczel, Entanglement: the greatest mystery in physics. Raincoast Books, Vancouver, (2002).

[8] A. Vaziri, G. Weihs, A. Zeilinger, Physical Review Letters 89 (2002) 240401.

[9] M. Hotta, J. Matsumoto, G. Yusa G (2014) Physical Review 89 (2014) 012311.

[10] M. A. Persinger, Perceptual and Motor Skills 88 (1999) 1210-1216.

[11] M. Bordag, U. Mohideen, V. M. Mostepanenko, Physics Reports 353 (2001) 1-205.

[12] R. Fickler, R. Lapkiewicz, W. N. Plick, M. Krenn, C. Schaeff, S. Ramelow, A. Zeilinger, Science 338 (2012) 640-644.

DOI: https://doi.org/10.1126/science.1227193

[13] T. Borowski, International Letters of Chemistry, Physics and Astronomy 1 (2012) 1-5.

[14] T. Borowski, International Letters of Chemistry, Physics and Astronomy 11 (2013) 44-53.

[15] M. A. Persinger, International Letters of Chemistry, Physics and Astronomy 12 (2013) 67-71.

[16] M. A. Persinger, S. A. Koren, The Open Astronomy Journal 6 (2013) 10-13.

[17] M. A. Persinger, S. A. Koren, Letters of Chemistry, Physics Astronomy 3 (2015) 35-43.

[18] Y. Hoffman, O. Lahav, G. Yepes Y. Dover, Journal of Cosmology and Astroparticle Physics 10 (2007) 1-16.

Show More Hide