The origin of orbital spacing and spin-axis obliquity in gravitational systems remains an open problem, typically attributed to a combination of disk evolution, migration, resonant interactions, and stochastic events such as impacts. While these mechanisms account for many observed features, a unified physical description linking orbital architecture and spin-axis organization has not been established. In this work, a mechanism is proposed in which rotation-induced Radial Waves arise at both microscopic and macroscopic scales. On the atomic scale, they generate electron energy levels that limit each radial wave to a maximum of two electrons with opposite spin orientations, and, on large scales, such as planetary systems, they produce increasing spacing between planetary orbits, with each wavelength region accommodating at most two planets exhibiting opposite rotational tendencies relative to their masses, in cases such as Venus and Earth, Ceres and Pallas, Uranus and Neptune, and Neptune and Pluto at perihelion. These Radial Waves are introduced as physical modulations generated by rotational dynamics, leading to spatially ordered regions that may influence both preferred orbital distances and spin-axis orientations. Within this framework, orbital spacing and obliquity are interpreted as responses to position within a structured radial field associated with the rotating central body. The proposed formulation is developed within the broader context of the Zero-field theoretical framework, in which rotational motion gives rise to organized spatial energy distributions. In this interpretation, Radial Waves are not introduced as oscillations in a conventional material medium, but as structured spatial variations associated with rotational energy flow. A qualitative correspondence is observed between radial structure and planetary-system architecture, including increased orbital spacing with distance and variations in axial tilt. To explore the physical plausibility of this mechanism, a conceptual experimental setup involving a rotating system and a coupled oscillatory probe is outlined to detect rotation-induced spatial modulation effects under controlled conditions. While the present work is exploratory and primarily qualitative, it suggests that rotationally induced radial structure may provide a unifying perspective on the origin of orbital spacing and spin-axis obliquity. Further investigation is required to establish the quantitative formulation, observational signatures, and experimental validation of the proposed mechanism.
Peyman Parsa (Sat,) studied this question.