Photon
In the Marias Theory, a photon is not a point-like or spherical particle as traditionally imagined in classical or quantum physics. Instead, a photon is a localized, vibrating structure of light β a wave packet with a coherent oscillation. It is a quantum of electromagnetic vibration with defined frequency, spin, and direction of propagation.
A photon is the most elementary form of energy manifestation, representing a unit of vibrational energy in the fabric of reality. It is not simply a carrier of force, but the very building block of matter itself when localized and condensed. According to this model, all particles β including electrons, protons, and even large structures β emerge from complex configurations of vibrational photons.
Core Properties of Photons in Marias Theory
- Vibrational Nature: A photon is a 3D oscillation of energy. Its structure is modeled as a coherent wave localized in space and time.
- Spin: The photon has an intrinsic spin, which in Marias Theory is tied to the rotation of its magnetic poles. This spin gives rise to polarization.
- Mass: Contrary to the classical notion of massless photons, the Marias Theory assigns a small but nonzero mass to photons.
This mass depends on the frequency of the photon and is calculated using the formula:
m = A Γ h Γ f / cΒ²
where A β 2.72 Γ 10β»ΒΉβΉ is the structural adjustment constant, h is Planckβs constant, f is frequency, and c is the speed of light. - Attraction: Photons attract each other due to their small mass. This interaction is extremely weak but nonzero, and it is the foundation for gravitational effects in the Marias Theory.
- Polarization: Polarization arises from the spin orientation. In coherent states, polarization is constant unless disturbed by external forces.
- Photon Interactions: Photons interact not by collision, but through synchronization and phase interaction of their oscillations.
Photon Behavior
In gravitational fields, photons are deviated not due to spacetime curvature, but due to the real gravitational pull resulting from their mass. This deviation is permanent, not symmetric as in general relativity. The photon continues on a new trajectory after interacting with a massive object.
Photons can attract each other weakly. In regions with dense radiation, such as near stars, this self-attraction becomes relevant, slightly altering light behavior.