A Unified Theoretical Framework Bridging Quantum Mechanics and Planetary Dynamics

Abstract
Quantum mechanics and planetary motion have traditionally been treated as separate domains governed by distinct principles. However, recent theoretical developments suggest a deeper connection between atomic-scale diffraction phenomena and large-scale gravitational interactions. In this work, a unifying theoretical framework is proposed, deriving planetary formation and motion from fundamental quantum diffraction principles. By reinterpreting classical orbital mechanics through a diffraction-based Hamiltonian, a natural continuity is established between the quantized behavior of atomic systems and the macroscopic dynamics of celestial bodies. The model challenges the conventional role of gravity in mass accumulation and planetary formation, suggesting that diffraction principles may play a fundamental role in structuring both atomic and planetary systems. This approach provides new perspectives on fundamental forces and opens pathways for experimental validation across multiple scales. Such an interpretation profoundly reshapes both frameworks and redefines the role of electrodynamical forces in the universe.