This title can also be given by the more physics oriented phrase “gravitational decoupling.” The idea that it exists is related to the idea of relativistic mass increase. High energy particle physics repeatedly demonstrated that the mass of a given particle increases in direct proportion as the increase of its linear velocity given by the simple formula ��=��₀/(1-��²/��²) where ��₀ is the rest mass, �� is the relativistic mass, �� is the magnitude of the linear velocity of the moving particle, and �� is the speed of light, here, it is given as the maximum attainable physical constant and not as a physical variable. It can be noted that as the value of �� approaches the value of ��, the denominator approaches the value of zero, consequently the value of the relativistic mass approaches infinity. In other words, the weight of a moving body gets heavier and heavier as it moves faster and faster in accordance with the principle of the theory of special relativity.

If the same principle of relativistic mass increase is applied to a spinning top then the particles near the center of gravity or center of mass of this rigid body must move faster than the particles on the outer rim in order to keep the smooth uniformity of its angular motion. On the other hand, the same cannot be said of a spinning basketball, since the particles of the rubbery outer layer are rigidly decoupled from the air particles inside such that if the basketball is spinning close to the speed of light, the mass of the outer rubber layer approaches infinity, while the mass of the motionless air particles near the center of gravity remains practically zero. Although this so called “gravitational decoupling” seems to exist physically, mathematically the center of gravity mass by abstract topological spherical symmetry remains located at the center of the basketball. This gives the physical paradox that an object can have zero mass and infinite mass simultaneously at a specified distance. If this specified distance is of the order of Planck length then its space-time configuration is identical to the local infinitesimal dynamics of the color topology of the quarks and gluons, distinguishing simultaneous properties of asymptotic freedom and infrared slavery. Nonetheless, the reverse is true for all atomic configurations; the motionless nucleus is many thousand times heavier than the fast orbiting electrons.