Theoretical Investigation of Resonance Phenomena and Information Density in Physical and Biological Systems

Description

Technical info

The proposed framework offers a mathematically elegant and physically plausible alternative to classical models, bridging conceptual gaps between quantum mechanics, cosmology, and biological systems. It presents a unified view of the universe as a resonant, interconnected harmonic system with implications for fundamental physics, information theory, and the life sciences.

Technical info

• A dynamic model of spacetime as a system of oscillations and resonances, extending Einstein’s relativity by incorporating frequency‑dependent time‑dilation effects.

• A resonance‑based explanation for black‑hole entropy and Hawking radiation, replacing singularities with stable resonance states.

• A modified Heisenberg uncertainty relation with a cosine‑based correction factor, enabling theoretical instantaneous information transfer and addressing the quantum information paradox.

• A resonance‑derived isotopic stability index that predicts the stability of nuclei such as Carbon‑12 and Lead‑208 by relating neutron numbers to powers of the Golden Ratio.

Technical info

The model provides a physics‑based framework for calibrating measurement devices in environments characterized by complex processes and fundamental uncertainties, such as nuclear and particle physics. It is particularly suited for detectors, spectrometers, and instruments measuring unstable isotopes or operating under quantum‑level uncertainties, enabling accurate calibration and interpretation despite inherent limitations (see Wigner’s friend).

Technical info

Matter is described not as static, but as dynamic and oscillatory. Forces emerge as coupling mechanisms between oscillations, producing stable, energetically favorable states that manifest as attraction. This principle explains the formation and persistence of structures across all scales of the universe, from microscopic to macroscopic.