The Quantum Emergent Vacuum: A Spectrally Bounded Framework for Physical Unification

We propose a framework in which the physical vacuum is described as a spectrally bounded medium rather than an unbounded quantum background. Vacuum fluctuations are restricted to a finite energy interval, bounded above by the hadronic confinement scale and below by a thermal transition scale associated with hadronic matter formation. This natural double bound removes the ultraviolet divergences of standard quantum field theory and yields a finite vacuum energy density without fine-tuning. Within this bounded interval we introduce a spectral density ρ(E), a discrete energy spectrum with degenerate levels, and damping factors that encode the entropic and thermal suppression of different energy modes. We formulate the hypothesis that the stable particles of the Standard Model arise as excitation patterns of this bounded vacuum spectrum. Gauge symmetries appear as symmetry groups of internally degenerate spectral structures, such that the full SU(3)×SU(2)×U(1) gauge structure emerges from this underlying organization. Coupling constants appear as geometric quantities determined by overlap integrals of spectral modes. In addition, we develop a thermodynamic formulation by introducing a spectral entropy and an effective temperature, allowing gravity to be interpreted as a thermodynamic response of the bounded vacuum spectrum to matter–energy distributions, in line with emergent-gravity ideas. We systematically present this emergent spectral vacuum model and explore its implications for vacuum energy, particle physics, and gravitational dynamics.