Two Physical Constraints upon the Motions of Celestial Bodies ()
ABSTRACT
There exist two physical constraints upon the motions of celestial systems. Constraint 1 reveals during collapse or explosion motion of celestial bodies that there would be an unattainability upper limit for their compact intensity (total mass M/scale size R), which arises from the Lorentz invariance of the time-like metric in local four-dimensional continuum in Einstein’s theory of special relativity. Constraint 2 points that the average mass density of nucleon would be an unsurpassed upper limit for bulk normal matter in nature, which arises from Heisenberg’s uncertainty principle. A very important effect is that the combination of these two physical constraints would prevent the formation of black holes.
Share and Cite:
Ai, X. (2019) Two Physical Constraints upon the Motions of Celestial Bodies.
Journal of Modern Physics,
10, 344-361. doi:
10.4236/jmp.2019.103023.
Cited by
No relevant information.