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The Big Bang (a working hypothesis) {© 03/12/17}

This paper, which was released on the 3rd of December 2017 by Keith Dixon-Roche (one of CalQlata's Contributors) represents a working hypothesis for the source and cause of the Big Bang.

Note: All the theories are provided by CalQlata's Laws of Motion, Core Pressure and The Atom
All the calculations are the sole copyright priority of Keith Dixon-Roche © 2017
Keith Dixon-Roche is also responsible for all the other web pages on this site related to planetary motions and properties
A 'pdf' version of this paper can be found at: Big Bang - The Paper


The purpose of this paper is to present a scenario that describes the Big Bang based upon the author's discoveries in Core Pressure and The Atom, and represents the universe as we see it today.


The hypothesis presented in this paper is viable as it is supported by known mathematical theories and reproduces a universe similar to that which we see today and provides the following information concerning the Big Bang and our universe:
The Big Bang occurred when the gravitational energy within a proton-star generated a pressure that compromised a proton's energy.
The proton-star had a mass of 4.68943E+48 kg
The energy released during the Big Bang was 4.49193E+56 J
The velocity of our Milky Way galaxy is 9787 m/s relative to the source of the Big Bang
The mass of the universe is the same as the mass of the proton-star
There are approximately 3.5137E+11 Milky Way galactic-masses in the universe
There are approximately 2.80364E+75 sub-atomic particles in the universe

The Body System

A Proton-Star


Determine the pressure required to compromise a proton using the theories of the atom and core pressure

Determine the size of a proton star that would generate such a pressure

Determine the energy released in the resultant explosion


It is assumed that the Big Bang occurred when a proton's integrity was compromised by gravitational force. This would occur when gravitational force (G.m₁.m₂/R²) is identical to Coulomb’s repulsion force (k.Q²/R²). We can use 'Core Pressure theory to find the mass that would generate this pressure.

Given that 'G.m₁.m₂.φ = k.Q²' at the radius of a proton in the very centre of a proton star when two adjacent protons are forced into contact
G is Newton's gravitational constant (6.67359232004332E-11 m³/kg/s²)
m₁ is the mass of a proton (1.67262163783E-27 kg)
m₂ is the mass of the proton star (? kg)
k is Coulomb’s constant (8.98755184732667E+09 N.m²/C²)
Q is the elementary charge (1.60217648753E-19 C)
φ is the ratio of electrostatic and gravitational forces (4.40742111792333E-40)
m₂ = k.Q² / G.m₁.φ = 4.68943E+48 kg

If each proton possesses the equivalent of 1.6021765E-19 J, the amount of energy released when the proton star exploded (i.e. when the protons were compromised) would have been 4.49193E+56 J

There are approximately 2.80364E+75 sub-atomic particles in the universe

If the mass of the proton star prior to the explosion is the same as the mass in the universe today (equivalent to 3.5137E+11 Milky Way galactic masses) the average velocity of all galaxies must be equal to √[E/m] relative to the centre of the explosion, i.e.:
v ≤ √[E/m] = 9787.15174 m/s

According to this scenario, the velocity we perceive relative to other galaxies must differ for each galaxy because each galaxy should be travelling away from us.

The above scenario (proton star as opposed to a neutron star) supports the concept of mass energy which would explode if compromised, whilst a solid lump would not.


Proposition 1: The Big Bang was caused by a star with the density of a proton at its centre, that was large enough to generate sufficient pressure from gravitational energy to compromise a proton

Proposition 2: The proton star had a mass of 4.68943E+48 kg

Proposition 3: There are approximately 2.80364E+75 sub-atomic particles in the universe

Proposition 4: The Big Bang explosion occurred at the centre of the proton star

Proposition 5: The energy released by the exploding proton star is 4.49193E+56 J

Proposition 6: The universe has a mass identical to the proton star

Proposition 7: The linear velocity of the Milky Way galaxy is 9787 m/s relative to the source of the Big Bang

Papers, Mathematical Symbols & Units

Newton's gravitational constant: G = 6.67359232004332E-11 m³/kg/s²

Coulomb's constant: k = 8.98755184732667E+09 N.m²/C²

Elementary charge: Q ≡ 1.60217648753000E-19 J

Universal density: ρ = 7.12660796350450E+16 kg/m³

Refer to the following pages for planetary properties used in the above calculations:
Laws of Motion
Core Pressure
The Atom

Further Reading

You will find further reading on this subject in reference publications(55, 60, 61, 62, 63, 64, 65 & 66)

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