Explorations in Astronomy & Astrophysics
ISSN: 3069-0811 | DOI: 10.64030/3069-0811
Alan Peter Garfoot
Dark Radiation, a new theoretical term for modeling the exotic emissions from black hole event horizons, proposes a unique quantum mechanical interaction between fundamental superstring types. Through which closed-loop hadronic strings, within the condensed matter state of black hole quark-gluon plasma, harmonically embed themselves, through resonant convergence, within open-end photonic energy-packet wavelengths. These embedded states of energy-matter symbiosis, in a synthesis of essential vibrationary nature, form metastable composite particles, dark radiation quanta termed "Axions". That occasionally escapes as nonthermal radiation from the gravitational hold of the singularity event horizon, when the precise quantum harmonic energy conditions allow for such a probability of such a quantum event's occurrence. This integrated dark radiation model places advanced string quantum dynamics, quantum tunneling probability frameworks, and zero-point perturbations in Schwarzschild metrics to explain rare, nonthermal radiation events triggered by Hawking Radiation events. These newly theorised emissions, uniquely different from Hawking radiation, theorize a fundamentally different radiation event governed by field resonance probability rather than thermal randomness. The theory is grounded in high-precision quantum field theoretical analysis, further reinforced through superstring harmonic modeling, and then supported through corresponding observed astrophysical anomalies and collected outlier evidence to theories and models current and established in the modern physics paradigm.