Wave–Particle Duality and Quantum Trajectories in the MMA–DMF Framework

We present a unified account of wave–particle duality and trajectory-level quantum phenomenology within the MMA–DMF framework, a deterministic scalar-field dynamics closed by a fluctuation–dissipation construction anchored at a fixed fundamental scale M = 100 TeV. We integrate, in a single reproducible narrative, the full battery of internal MMA–DMF tests spanning microphysics, weak-measurement trajectory reconstruction, dynamical contextuality, atom-interferometric decoherence constraints, astrophysical spectral drift (the “sad trombone” effect), topological mass/charge clustering, neutrino seesaw scaling, gravitational-wave echo predictivity, and cosmological/null-search checks including the scalar-vacuum stochastic background estimate for LIGO O4a [16]. For each test we state the identifier, date, aim, setup, numerical/analytical method, observables, quantitative outcome, and the way the result constrains MMA–DMF. The most recent locked audit results are adopted as final whenever multiple versions exist. Three representative figures are inserted at the exact points where they are discussed: spectral drift (T-Spectral), visibility collapse under coupling removal (WPD), and deterministic sensitivity/chaos diagnostics (QT). Overall, MMA–DMF passes the suite at the level of internal consistency and observational non-contradiction, while isolating concrete predictive handles (echo delays; roll-off in Bell-type correlations under ultra-fast switching) and open requirements (full experimental confrontation and controlled systematics).