Oxygen \(O\), that exists as a gas, \(O_2\), at room temperature suggests the absence of negative gravity particles in spin that manifest a magnetic force that holds the material as a solid. Temperature particles (positive and negative particles) in spin present the electrostatic force or the gravitational force. Both these forces are weak and do not hold a material solid. And, as we extend the model to include many negative gravity particles, a resultant magnetic force is the result of an unbalanced spin among the spinning particles.
Statements more suitable in a religious context than science.
But none the less, this proposed effect of unbalance spinning negative gravity particle, is consistent with the fact that carbon \(C\) (less atomic mass but with unbalanced spinning negative gravity particles), is a solid but nitrogen \(N\) (more atomic mass but without unbalanced spinning negative gravity particles), is a gas, \(N_2\) at room temperature.
This conjuncture still allows for increasing atomic mass with increasing number of negative gravity particles across the Periodic Table, as we expect intuitively. So, it is wrong to say \(O\), has no gravity particles. It has mass! Instead, \(O_2\) has no unbalanced spinning negative gravity particles.
And it is the spins of negative gravity particles that matters. In the case of large cosmic spin, the presence of this magnetic field along the axis of rotation of negative gravity particles, collapses all magnetic material into a disc perpendicular to the axis of rotation.
Yes, I am building my very own, personal universe.
The introduction of positive temperature particles (heat) weakens a solid and at high enough temperature melts the solid, ie the melting point. The introduction of negative temperature particles (freeze) also weakens a solid and at low enough temperature causes it to fracture. We should call this temperature the fracturing point. The difference is: Positive temperature particles in spins manifest a electrostatic force that interacts with positive charges in the material and repels the material apart; at its melting point the material flows apart. Negative temperature particles on the other hand manifests a gravitation force in spins, this force however attracts the negative gravity particles in the material. The material hold firm at low temperature, but fractures. The force that holds a solid rigid is the magnetic force, "carried by" temperature particles and is weakened by the introduction of temperature particles into the material.
What of positive gravity particles?? Particles with gravity field lines pointing outwards??
mass \(\equiv\) negative gravity particles
positive gravity particles \(\equiv\) ??