Strong Force as Localized Gravity
Why is the strong nuclear force so powerful at short ranges but ineffective at larger scales? How does it overcome electromagnetic repulsion in nuclei?
Timothian Model's Short Answer...
The strong force emerges from intense local chunk displacement by atomic seeds, creating powerful stratification tensions analogous to gravity at subatomic scales.
Details
The Timothian Model reinterprets the strong nuclear force as a localized gravitational effect:
Atomic Seed Displacement: Conglomerated chunks in atomic seeds create intense local chunk medium displacement.
Stratification Tensions: The surrounding medium stratifies by density, similar to gravitational effects at larger scales.
Restoration Force: Strong tension between the displacing seed and stratified medium holds the nucleus together.
Stratification Spheres: Concentric spheres of same-species chunks form around the seed, maintaining nuclear stability.
Energy Barrier: The integrity of stratification spheres must be overcome for nuclear reactions or decay to occur.
Short Range: Intense effects localized to nuclear scale due to extreme displacement gradients.
Unification with Gravity: Strong force emerges as the same phenomenon as gravity, but at subatomic scales.
Nuclear Binding Energy: Reflects the energy stored in chunk displacement and stratification.
Nuclear Reactions: Occur when sufficient energy allows rearrangement of chunk configurations and stratifications.
This approach unifies the strong force with gravity, providing a consistent explanation across all scales.
Related Documents in the Full Timothian Model
The Nature of Atoms, Charge, & Chemical Bonds: Explores atomic structure and the strong force.
The Nature of Gravity: Connects nuclear and gravitational forces.
The Nature of Energy: Examines energy storage and release in nuclear processes.