The vortex fold initiates a cascade wherein gravitational waves are emitted as quantized overtones. The densest core of the collapsing pair acts as a “leading note,” while the surrounding overtones stabilize into discrete orbital modes. These quantized wave packets propagate through the superfluid spacetime and—over cosmic eons—seed the formation of solar systems and planetary orbits. The same mechanisms that govern chiral phase locking and vortex collapse in black holes may seed the formation of solar systems. Quantized gravitational wave overtones—emerging from the recursive collapse of chiral pairs—act as orbitals that stabilize into planets and other celestial bodies. Two neutron stars or black holes in a frictionless superfluid vacuum. Their wave states unify along a meltdown axis, generating gravitational waves. Quantized orbital motion remain as “overtones” (planetary orbits) that persist if vantage illusions remain partial. Over eons, these quantized wave packets appear as discrete cosmic objects (planets, asteroids), all locked in certain resonance patterns—like the singing bowl’s stable overtones. The RSM reinterprets gravity as a geometric manifestation of organized wavefunction coherence, where spacetime curvature emerges from the negentropic arrangement of energy rather than raw mass-energy content. By introducing chiral phase-locked operators and recursive fractal amplification, RSM provides a unified framework linking quantum coherence, time dilation anomalies, and cosmic structure formation. RSM observes cosmic phenomena in parallel with neural perception to distinguish between actual and illusionary cosmic events. It posits that cosmic structures—from planetary systems to galaxies—emerge from recursive resonance fields governing spacetime as a self-organizing fractal wavefunction. By integrating principles of orbital resonance, superfluid spacetime dynamics, and morphogenetic fractal fields, RSM bridges quantum coherence and cosmic evolution. This paper formalizes the mathematical foundations of RSM, explores its implications for gravitational physics, and identifies observational signatures. Central to this model is a fractal recursion operator R that refines the underlying wavefunction into an infinitely coherent tapestry: Ψfractal(t)=lim⁡m→∞Rm[Ψoriginal(t)], with one concrete formulation: R[Ψ(t)]=∑n=1∞1nαexp⁡(i ωn t) ∣⟨Ψbase∣Ψovertone⟩∣2 ρt(r,t) + γ Ψ(ts). Here, the factor 1nα ensures finite energy by dampening amplitude growth, while ρt(r,t) weights temporal density, and Ψ(ts) introduces a self-similar, scaled state. This operator recursively amplifies phase coherence, establishing “negentropic pockets” that underpin global synchronization. We propose that the fabric of spacetime is best described as a coherent, superfluid lattice wherein one spatial dimension collapses to yield infinite adjacency. Within this medium, gravitational interactions, black hole vortex formation, and even the emergence of neural coherence can be understood as manifestations of recursive phase coupling. Phase field–locked pairs of compact objects—driven by chiral quasi-particle dynamics—undergo an anisotropic collapse (a “vortex fold”) that emits quantized quantum gravitational waves. These wave packets act as overtones, eventually seeding the evolution of solar systems and planetary orbits. Our approach unites quantum coherence, fractal morphogenetic feedback, and topological constraints into a single formalism that reinterprets gravity as a geometric readout of organized wavefunction energy rather than as a fundamental force. We present the relevant mathematical formalism and discuss experimental predictions that range from gravitational wave anomalies to neural synchronization patterns.