All Title Author
Keywords Abstract

Publish in OALib Journal
ISSN: 2333-9721
APC: Only $99


A Snapshot of a Homogeneous Spinning Universe

DOI: 10.4236/oalib.1104895, PP. 1-11

Subject Areas: Classical Physics, Classical Mechanics, Modern Physics

Keywords: Celestial Mechanics, Newtonian Gravitation, Newton’s 2nd Law, Theory of Relativity, Perihelion Precession, Cosmology

Full-Text   Cite this paper   Add to My Lib


A snapshot of the circular speed as a function of the radius in a spin-ning-homogeneous spherical universe was obtained using a mass-dependent characteristic-acceleration in the Modified Newtonian Dynamics (MOND paradigm as a modified 2nd law of Newton) with and without considering the impact of the relativistic speed. To consider the impact of the relativistic speed the Extended Newtonian Theory (ENET), previously developed by the author, was used. The corresponding kinetic energy equation for ENET is however reported in this work for the first time. The speed profile shows a non-linear trend with features that has been experimentally noted before. It was shown that the Hubble law (for circular speeds) can be inferred from the results for a distance range close to the experimental results of the Hubble telescope key project. The calculation considering the impact of the relativistic speeds yields a very distinctive tail towards the edge of the universe that has been noted before. It is striking that a spinning universe model yields (without any reference to dark matter or dark energy) observed features of a universe which, based on photometric and spectral line measurements, is currently interpreted as radially expanding at an accelerated rate.

Cite this paper

Quintero-Leyva, B. (2018). A Snapshot of a Homogeneous Spinning Universe. Open Access Library Journal, 5, e4895. doi:


[1]  Hubble, E. (1929) A Relation between Distance and Radial Velocity among Extragalactic Nebulae. Proceedings of the National Academy of Sciences of the United States of America, 15, 168-173. Astronomy.
[2]  Zwicky, F. (1929) On the Red Shift of Spectral Line through Interstellar Space. Proceedings of the National Academy of Sciences of the United States of America, 15, 773-779. Physics.
[3]  Riess, et al. (1998) Observational Evidence from Supernovae for an Accelerating Universe and a Cosmological Constant. arXiv:astro-ph/9805201v.
[4]  Zwicky, F. (1933) The Redshift of Extragalactic Nebulae. Republication. Springer Science Business Media LLC 2008.
[5]  Bertone, G. and Hooper, D. (2016) A History of Dark Matter. FERMILAB-PUB-16- 157-A (astro-ph.CO. arXiv:1605.04909v2).
[6]  Zorba, S. (2012) Dark Energy and Dark Matter as Inertial Effects. arXiv:1210.3021. [physics.gen-ph]
[7]  Berman, M.S. (2013) Realization of Einstein’s Machian Program. arXiv:1302.2498v1 [physics-gen-ph]
[8]  Berman, M.S. and Gomide, F. (2013) Local and Global Stability of the Universe. Journal of Modern Physics, 4, 7-9.
[9]  (2018)
[10]  Quintero-Leyva, B. (2017a) On the Extension of the Baryonic Tully-Fisher Relation to Galaxy Clusters and Super Massive-Cosmic Systems. Open Access Library Journal, 4, e3686.
[11]  Milgrom, M. (1983a) A Modification of the Newtonian Dynamics as a Possible Alternative to the Hidden Mass Hypothesis. Astrophysical Journal, 270, 365-370.
[12]  McGaugh, S.S., et al. (2010) The Baryon Content of Cosmic Structures. The Astrophysical Journal, 708, L14-L17.
[13]  (2018)
[14]  Segal, I.E. and Nicoll, J.F. (1992) Apparent Nonlinearity of the Redshift-Distance Relation in Infrared Astronomical Satellite Galaxy Samples. Pro-ceedings of the National Academy of Sciences of the United States of America, 89, 11669-11672. Astronomy.
[15]  Quintero-Leyva, B. (2016) An Extended Newtonian Theory for Gravitational Bound Systems. Open Access Library Journal, 3, e2678.
[16]  Ashmore, L. (2006) Recoil between Photons and Electrons Leading to the Hubble Constant and CMB. Galilean Electrodynamics, 17, SI No. 3.


comments powered by Disqus

Contact Us


WhatsApp +8615387084133

WeChat 1538708413