Quantum Mediator Cycle Theory (QMCT)
A Cyclic Extension of Mediator Dynamics via Hidden Interaction Domains
Author
Aswin B S
Founder, SHERMODZ
Independent Researcher in Theoretical Physics
Kerala, India
Email: aswinbsd7@gmail.com
Abstract
Quantum Mediator Cycle Theory (QMCT) proposes that fundamental interactions are part of a cyclic process involving mediator particles and a hidden interaction domain termed the Astra Plane (ABS Space). While quantum field theory describes forces as local exchanges of virtual particles, QMCT introduces an additional non-local component in which mediators propagate through ABS Space, forming closed interaction loops. The framework preserves the mathematical structure of Quantum Electrodynamics (QED) while introducing a small self-energy correction to mediator propagators. This leads to testable predictions in high-energy scattering experiments. A speculative connection to cosmological energy flow and black hole thermodynamics is also discussed.
1. Introduction
The Standard Model of particle physics describes fundamental interactions through quantum field theory. In Quantum Electrodynamics (QED), electromagnetic interactions arise from the exchange of virtual photons.
The classical force between charges is:
F =\frac{1}{4\pi\epsilon_0}\cdot\frac{q_1 q_2}{r^2}
In QED, interactions are described by the Lagrangian:
\mathcal{L}_{int}=-q\bar{\psi}\gamma^\muA_\mu\psi
Despite its success, this framework does not provide a structural interpretation of interaction beyond probabilistic exchange.
QMCT proposes a cyclic and partially non-local interpretation of mediator dynamics while preserving established physics.
2. Conceptual Framework
2.1 Mediator Structure Interpretation
QMCT interprets the interaction field as a dense sequence of virtual quanta:
A_\mu(x)\sim\sum_i\gamma_i^{(virtual)}
This suggests an effective continuous interaction structure between particles.
2.2 Rope Interaction Model
Interactions are interpreted using two tendencies:
| Charges |
Interaction |
Result |
|
Push–Push |
Repulsion |
|
Pull–Pull |
Separation |
|
Push–Pull |
Attraction |
This model is interpretational and does not replace Coulomb’s law.
3. Extended Field Description
QMCT introduces:
A_\mu = A_\mu^{(local)} + A_\mu^{(ABS)}
Where:
- : standard field
- : hidden component
Constraint:
A_\mu^{(ABS)} \rightarrow 0 \quad \text{at experimentally tested scales}
4.Astraplane( ABS PLANE)
4.1 Definition
A hypothetical auxiliary domain enabling intermediate mediator propagation.
4.2 Cyclic Interaction Condition
\oint A_\mu \, d\lambda = C \neq 0
This represents a closed interaction loop.
5. Matter–Antimatter Symmetry Extension
\gamma^{(virtual)} : e^- \rightarrow \text{ABS} \rightarrow e^+
This expresses a symmetry relation, not particle conversion.
6. Energy Considerations
6.1 Hawking Radiation
T_H = \frac{\hbar c^3}{8\pi G M k_B}
P \propto \frac{1}{M^2}
6.2 QMCT Energy Hypothesis
E_{total} = E_{local} + E_{ABS}
E_{ABS} = \alpha E_{cosmic}, \quad \alpha \ll 1
7. Extension to Other Interactions
| Interaction |
Mediator |
QMCT Role |
| Electromagnetic |
Photon |
Cyclic mediator |
| Strong |
Gluon |
Confined cyclic dynamics |
| Weak |
W/Z |
Decay-linked cycles |
8. Higgs Field Interpretation
m = y v
QMCT modification:
v = v_0 + \delta v_{ABS}, \quad \delta v_{ABS} \ll v_0
m = y (v_0 + \delta v_{ABS})
9. Testable Prediction: Propagator Correction
9.1 Standard Propagator
D_{\mu\nu}(k) = \frac{-i g_{\mu\nu}}{k^2 + i\epsilon}
9.2 QMCT Modification
D_{\mu\nu}^{(QMCT)}(k) =
\frac{-i g_{\mu\nu}}{k^2 - \Pi_{ABS}(k^2) + i\epsilon}
\Pi_{ABS}(k^2) = \alpha \cdot \frac{k^2}{k^2 + \Lambda_{ABS}^2}
9.3 Observable Effect
\frac{d\sigma}{d\Omega} \propto
\left| \frac{1}{k^2 - \Pi_{ABS}(k^2)} \right|^2
For small :
\Delta \sigma \propto \alpha \cdot \frac{1}{k^2 + \Lambda_{ABS}^2}
9.4 Experimental Implications
- Negligible effect at low energy
- Small deviation at high energy
- Testable in particle accelerators
10. Discussion
QMCT:
- Preserves Standard Model equations
- Adds a cyclic interpretation of mediator dynamics
- Introduces a hidden interaction domain
- Suggests a cosmological energy connection
11. Limitations
- ABS Space is hypothetical
- No direct experimental evidence
- Not derived from gauge symmetry
- Requires deeper theoretical development
12. Conclusion
Quantum Mediator Cycle Theory (QMCT) proposes that:
- Interactions may be cyclic
- Mediator particles may propagate through hidden domains
- Small measurable deviations may exist at high energies
This framework extends quantum field theory while remaining consistent with known experimental results.
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