Quantum Mechanics Without Collapse

We develop a structural reinterpretation of the foundational ontological problems of quantum mechanics within the program of Metamonism 1 and its physical extension Basic Ontodynamics 2. Three ontological placeholders that have resisted satisfactory interpretation for a century — wave function collapse, wave-particle duality, and virtual particles — are identified as symptoms of a foundational gap: the absence of a structural account of what quantum objects are. The present framework proposes that quantum objects are activation regimes of the F-hierarchy at different degrees of F7 closure. The photon is F56 without F7 — an unclosed coherence regime. The electron is F56 with residual St closure. Wave-particle duality dissolves: there is one object at different closure states, not two natures. Collapse dissolves: measurement is a continuous F7 closure process driven by structural resonance, not a discontinuous transition. Virtual particles dissolve as ontological entities: interactions are direct F56 coherence redistributions through the shared background F123, with virtual particles as mathematical parametrizations of transient incomplete F7 closures. The uncertainty principle receives a structural reading: ∆x · ∆p and ∆E · ∆t are two aspects of the single constraint that F7 closure and F56 phase sharpness cannot be simultaneously maximal. Renormalization is identified as a symptom of ontological incompleteness: it compensates for the point particle idealization, the free propagator treatment of virtual particles, and the empty vacuum assumption— all of which the F-hierarchy framework replaces structurally. Five falsifiable predictions are stated: finite duration of atomic transitions, natural ultraviolet cutoff in vacuum fluctuations, vacuum birefringence at high laser intensity, confinement scale from F7 closure geometry, and renormalization group fixed points as F7 closure transitions. The paper is a programmatic contribution within Metamonism: it proposes a structurally unified ontological reading of quantum phenomena and establishes a research program in which the formal derivation of quantum mechanics from F-hierarchy dynamics becomes a well-posed task.