Is reduced Planck’s constant- an outcome of electroweak gravity?

To understand the mystery of final unification, in our earlier publications, we proposed that there exist three atomic gravitational constants associated with electroweak, strong and electromagnetic interactions. During cosmic evolution, if one is willing to give equal importance to Higgs boson and Planck mass in understanding the massive origin of elementary particles, then it seems quite logical to expect a common relation in between Planck scale and Electroweak scale. Based on these two points, we noticed that, electroweak field seems to be operated by a primordial massive fermion of rest energy 585 GeV. It can be considered as the zygote of all elementary particles and galactic dark matter. H-bar seems to be a characteristic outcome of unified electroweak gravity. Electron rest mass seems to be a characteristic outcome of electroweak and strong gravity. Proton rest mass seems to be a characteristic outcome of electroweak, strong and electromagnetic gravity. Recently observed 3.5 keV photon seems to be an outcome of annihilation of charged baby lepton of rest energy 1.75 keV. Interesting point to be noted is that, Schwarzschild radius of electron is 0.48 nanometer and it needs further investigation with respect to emerging nanoscience and technology. Proceeding further, by considering electromagnetic and weak gravitational constants, neutron life time can be understood.


Introduction
Even though celestial objects that show gravity are confirmed to be made up of so many atoms, so far scientists could not find any relation in between gravity and the atomic interactions at quantum gravity level [1,2]. Black hole temperature point of view [3], strong interaction point of view [4][5][6][7] and electroweak interaction point of view [8], scientists found very interesting similarities in between gravity and quantum phenomena. Quantum cosmology point of view [9] and nuclear quantum gravity point of view [10][11][12][13][14][15][16][17][18][19][20], authors could develop workable ideas, concepts and relations. On a whole, workability is still lagging. It clearly indicates that, there is something wrong in our notion of understanding or there is something missing in developing the unified physical concepts and needs a critical review at fundamental level. In this context, we hope that, electroweak scale [21,22,23] can certainly yield useful stuff.

Motivating concepts
To develop new and workable ideas, we wish to highlight the following points.
1) During cosmic evolution, if one is willing to give equal importance to Higgs boson and Planck mass in understanding the massive origin of elementary particles and observed matter [24,25], then it seems quite logical to expect a common relation in between Planck scale and Electroweak scale. 2) Whether particle's massive nature is due to electromagnetism or gravity or weak interaction or strong interaction or cosmic dust or dark matter [26] or something else, is unclear. 3) Without understanding the massive nature, it is not reasonable to classify the field created by any elementary particle. 4) All the four interactions seem to be associated with    . 5) Nobody knows the mystery of    which seems to be a basic measure of angular momentum [27,28,29,30]. 6) Nobody knows the mystery of existence, stability and behavior of 'proton' or 'electron'. 7) 'Mass' is a basic property of space-time curvature and basic ingredient of angular momentum. 8) Atoms are mainly characterized by protons and electrons. 9) 'Free neutron' is an unstable particle.

Characteristic unified relations
Based on the above points, we propose the following new and workable relations.
With reference to 19 6.7494 10 m With reference to electromagnetic gravitational constant, Schwarzschild radius of electron can be addressed with, Based on relations (14) and (15)

Specific unified relations connected with nuclear stability and binding energy
Nuclear mean stability and binding energy [44,45] can be understood with the following two relations.
Nuclear mean stability can be understood with,   Nuclear binding energy can be understood with,

Specific unified relations connected with stellar mass limits
With reference to strong nuclear gravitational constant and astro-physics point of view [14,16], by considering nucleon as a characteristic building block, stellar mass limit [46,47] can be understood with a relation of the form, Thus, characteristic stellar mass limit can be estimated with a very simple relation of the form,   3 2

solar masses
Another interesting relation is, 3 2

solar masses
With reference to electromagnetic gravitational constant, mass limits of super massive stellar objects can be understood.

10.
Applications of e G in elementary particle physics and astrophysics A) Understanding the recently observed 3.5 keV galactic photon Recent galactic X-ray [48,49] studies strongly confirm the existence of a new photon of energy 3.5 keV. So far, its origin is unknown and unclear. In this context, we propose the following alternative mechanism for understanding the origin of 3.5 keV photon.
1) There exists a characteristic charged baby lepton of rest mass,   can be generated.

B) Fitting Muon and Tau rest masses
Experimentally observed [29] Muon and Tau rest masses can be fitted in the following way.  2)   s G can be estimated from relations (8)(9)(10).
3)   w G can be estimated from relation (1).

Understanding neutron life time with
One of the key objectives of any unified description is to simplify or eliminate the complicated issues of known physics. Neutron life estimation is one of such complicated issue [29,50,51]. In this context, in our earlier publications [20,52], we proposed the following relations.
    In this way, bottle method [50] and beam method [51] of neutron life time experiments can be correlated with confined and moving neutrons.

Discussion
We appeal that, (1) Success of any unified model depends on its ability to involve gravity in microscopic models. (2) Full-fledged implementation of gravity in microscopic physics must be able to: a) Estimate the ground state elementary particle rest masses of the three atomic interactions. b) Estimate the coupling constants of the three atomic interactions. c) Estimate the range of all interactions. d) Estimate the Newtonian gravitational constant.
(3) As the root/path is unclear and unknown, to make it success or to have a full-fledged implementation, one may be forced to consider a new path that may be out-of-scope of the currently believed string theory models [53]. (4) In our approach, a) We assign a different gravitational constant for each basic interaction. b) Considering 585 GeV fermion as the characteristic building block of all elementary particles, an attempt is made to fit proton and electron masses. c) During this journey, without considering arbitrary numbers or coefficients, we come across many strange and interesting relations for estimating other atomic and nuclear coupling constants. d) Based on relations (5) and (6)