Disturbance Wave Theory: A Comprehensive Mechanistic Enhancement of QCD Phenomena

Quantum chromodynamics (QCD) describes confinement, asymptotic freedom, chiral symmetry breaking, mass generation, and proton spin through phenomenological models, lacking a unified mechanistic foundation. We propose a ``Disturbance Wave Theory,'' where quark-gluon interactions generate dynamic waves (\( f = \frac{\Delta E}{h} \)) with energy fluctuations (\( \Delta E \sim 220-242 \, \text{MeV} \)) from base (\( 200 \, \text{MeV} \)) and action (\( 20-42 \, \text{MeV} \)) fields. This framework unifies QCD phenomena: confinement via wave-induced linear potentials, asymptotic freedom through frequency scaling, chiral breaking by oscillatory condensates, mass generation from gluon energy dominance, and proton spin via collective wave angular momentum. Transitioning QCD from descriptive to mechanistic, we provide detailed predictions at \( f \sim 10^{22} \, \text{Hz} \) for spectroscopy, deep inelastic scattering (DIS) and lattice QCD, enhancing theoretical rigor and experimental testability.