Author(s)

Donald William Chakeres^1*, Richard Vento²

¹Department of Radiology, The Ohio State University, Columbus, USA.
²Columbus State Community College, Columbus, USA.

Purpose: To accurately derive H₀ from subatomic constants in abscence of any standard astronomy data. Methods: Recent astronomical data have determined a value of Hubble’s constant to range from 76.9^+3.9_-3.4^+10.0_-8.0 to 67.80 ± 0.77 (km/s)/Mpc. An innovative prediction of H₀ is obtained from harmonic properties of the frequency equivalents of neutron, n⁰, in conjunction with the electron, e; the Bohr radius, α₀; and the Rydberg constant, R. These represent integer natural unit sets. The neutron is converted from its frequency equivalent to a dimensionless constant,, where “h” = Planck’s constant, and “s” is measured in seconds. The fundamental frequency, V_f, is the first integer series set . All other atomic data are scaled to V_f as elements in a large, but a countable point set. The present value of H₀ is derived and Ω_M assumed to be 0. An accurate derivation of H₀ is made using a unified power law. The integer set of the first twelve integers N₁₂ {1,2,…,11,12}, and their harmonic fractions exponents of V_f represent the first generation of bosons and particles. Thepartial harmonic fraction, -3/4, is exponent of V_f which represents H₀. The partial fraction 3/4 is associated with a component of neutron beta decay kinetic energy. Results: H₀ is predicted utilizing a previously published line used to derive Planck time, t_p. The power law line of the experimental H₀ and t_p conforms to the predicted line. Conclusions: H₀ can be predicted from subatomic data related to the neutron and hydrogen.

Hubble Constant, Neutron, Unification Model, Planck Time, Quantum Gravity, Neutron Beta Decay, Neutrino

Chakeres, D. and Vento, R. (2015) Prediction and Derivation of the Hubble Constant from Subatomic Data Utilizing the Harmonic Neutron Hypothesis. Journal of Modern Physics, 6, 283-302. doi: 10.4236/jmp.2015.63033.