TITLE:
Prediction and Derivation of the Hubble Constant from Subatomic Data Utilizing the Harmonic Neutron Hypothesis
AUTHORS:
Donald William Chakeres, Richard Vento
KEYWORDS:
Hubble Constant, Neutron, Unification Model, Planck Time, Quantum Gravity, Neutron Beta Decay, Neutrino
JOURNAL NAME:
Journal of Modern Physics,
Vol.6 No.3,
February
27,
2015
ABSTRACT: 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, Vf, is the first integer
series set . All other atomic data are scaled to Vf as elements in a large, but a countable point set. The present value of H0 is derived and ΩM 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 Vf represent the first generation of
bosons and particles. Thepartial harmonic fraction, -3/4, is exponent of Vf 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, tp.
The power law line of the experimental H0 and tp conforms to the
predicted line. Conclusions: H0 can be predicted from subatomic
data related to the neutron and hydrogen.