We present a falsifiable field-theoretic framework unifying quantum measurement, cosmic acceleration, and observer physics through φ-based geometric organization of temporal branching. The theory proposes: (1) spacetime is five-dimensional (M⁴ × B), where B is a branch manifold with coordinates spaced at the golden angle θ = 2π (1-φ⁻¹) ≈ 137. 508° to prevent topological collision (No Double Occupancy principle) ; (2) measurement implements an Observer-Dependent Temporal Filter (ODTF) that samples discrete branches via quantum Zeno effect; (3) cumulative branch surface area generates vacuum energy through holographic surface tension, manifesting as observed dark energy (ρDE ∝ Aₛurface/V). This framework addresses: the measurement problem (branching without collapse), the cosmological constant problem (explaining dark energy onset at z~0. 7), and electromagnetic coupling (deriving α⁻¹ ≈ 137 from branch geometry). We provide explicit Lagrangian formulation ℒ = ℒₘatter + ℒbranch + ℒcoupling, demonstrating UV-finiteness via holographic cutoff and energy conservation through zero-energy universe dynamics. Six testable predictions distinguish this from standard Many-Worlds: (1) φ-periodicity in quantum measurement statistics; (2) neural oscillations following φ-progressions (theoretical support: Pletzer 2010, Kramer 2022) ; (3) correlation between H (z) and integrated stellar mass density with exponent α ≈ 0. 52; (4) CMB temperature anisotropies at Fibonacci multipoles ℓ = 137, 222, 360,. . . ; (5) gravitational decoherence scaling; (6) fine structure constant variations proportional to sin (2πφⁿz). Three protocols executable immediately using public data (Planck CMB, cosmic chronometers, EEG archives) with explicit falsification criteria (p 0. 7).
Sharukhan A (Mon,) studied this question.
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