What Is Gravity? How Does Mass Create Gravity?
Gravity, one of the most fundamental forces in the universe, can be understood through the lens of a quantized elastic spacetime framework. In this model, space is not a smooth continuum but rather a dynamic network of interconnected space elementary quanta (SEQ), bound by spring-like elastic bonds. These SEQ form a flexible structure where distortions propagate as energy, much like vibrations in an elastic material. This discrete fabric of spacetime allows us to reinterpret gravity not as a mysterious "force at a distance" but as an emergent phenomenon arising from the mechanical deformation of this quantum network.
Mass, in this context, is a compressed state of spacetime. When matter exists, it locally increases the density of SEQ, creating a region where the spacing between these quanta is reduced. This compression generates tension in the surrounding network—Mass and gravity operate like a cosmic spring: compressing one segment (mass) dynamically stretches the entire remaining network (gravity), creating a space-time tension(gravitational) field where the space network store potential energy. The greater the mass, the stronger the compression, and the deeper the resulting curvature in spacetime. Crucially, this curvature is not merely geometric but dynamic: the compressed region alters the harmonic oscillation frequencies of nearby SEQ, slowing their transformation rates. This matches the time dilation effects predicted by general relativity, revealing gravity as a consequence of space elastic mechanics.
Gravity itself manifests as a stretched state of spacetime—a divergent translation of SEQ network radiating outward from the mass. The tension propagates spherically, with its influence diminishing by the inverse-square law, consistent with Newtonian and Einstein gravity. The topological curvature of spacetime, described by general relativity’s metric changes, emerges naturally from this imbalance: compressed SEQ near mass "pull" the surrounding network inward, while the stretched regions exhibit reduced oscillation frequencies, causing the observed gravitational redshift and time dilation. Notably, this model resolves the black hole singularity paradox by imposing an upper limit on SEQ tension, preventing infinite curvature.
In summary, gravity arises from the interplay between mass-induced compression and the elastic response of quantized spacetime. Mass deforms the SEQ network, creating tension that propagates as gravitational influence, while the stretched spacetime regions encode the familiar effects of curvature and time dilation. This framework not only demystifies gravity but also bridges quantum mechanics and general relativity through the mechanics of a dynamic, discrete spacetime fabric.
