CC BY
7Complex Systems of Charged Particles and their Interactions with Electromagnetic Radiation 2017
REDICTED COLD STERILE NEUTRINO COSMIC BACKGROUND SATISFIES CHANDRASEKHAR WHITE DWARF MASS LIMIT
Charles K. Rhodes
Laboratory for X-Ray Microimaging and Bioinformatics Department of Physics University of Illinois at Chicago Chicago, IL 60607-7059, USA
Several predicted features of the Cosmic realm have been produced from a new cryptographic analysis that is based on the concept of an optimized and maximally ordered Universe that perforce obeys a condition of minimum entropy. The quantitative findings of this cosmic picture include the computation of the Fine Structure Constant a, a Sterile Neutrino vs mass of 27.45 meV, the Cosmological Constants QA and Qm, the Luminous Matter Fraction Ql, the Cosmic Neutrino Background (CNB) density pv, and the value Tv = 0 for the temperature of the CNB. Likewise predicted was the existence of a very massive DARK MATTER counterpart Ql' of the Luminous Fraction Ql that obeyed the remarkable relationship Ql/Ql'~ QA/Qm = 2.74, valid to one part in ~1060, hence, observationally exact. The total mass of the unknown Dark Matter object associated with Ql' was computed to be Md = 2.6213 • 1054 g, with the level of accuracy limited by the uncertainty in the Gravitational Constant G. The arithmetic structure of the calculated mass identified it as a single coherent monolithic body. We demonstrate that this mass, with a presumed composition of cold degenerate Fermi matter consisting solely of light Sterile Neutrinos vs, matches well the value MCh
expected if it had arisen from the formation of the neutrino equivalent of a White Dwarf star at the
28
Chandrasekhar Limit, hence, Md ~ MCh. The radius R* of this entity is also shown to be -1.6^ 10 cm, a magnitude that very adequately corresponds to the estimates of the radius of the observable Universe. Hence, a measurement of the Luminous Matter Fraction Ql yields an indirect quantitative determination of the mass of a Dark Matter object, the Sterile Neutrino vs, that fits a coherent analysis of the Cosmic Domain. Furthermore, since previously established results precisely interrelate all of the physical quantities of the {a, QA, Qm, Ql} tetrad, this striking predictive property holds equivalently for the entire membership of the quartet. This finding motivates the conjecture that the properties of many forms of Dark Matter may be readily discovered and indirectly measured through knowledge of comparable reciprocal relationships associating the characteristics of Luminous and Dark Matter.
