Standard relativistic quantum mechanics, including the Klein–Gordon and Dirac equations, is recovered here as the screened, flat-frame tangent limit of a deeper dynamical proper-time phase transport governed by the Temporal Equivalence Principle (TEP). By treating proper time τ as a dynamical scalar field φ rather than a universal parameter, three foundational structures are derived and two are geometrically reinterpreted. (1) The phase action S = −mc² ∫ dτ̃ emerges as the primitive geometric driver, with mass appearing in the primitive action as the parameter governing the oscillator frequency, ω₀ = mc²/ℏ, modulated by the conformal factor in the causal matter metric g̃μν. (2) The Klein-Gordon equation is derived from the minimal geometric Lagrangian in the causal metric and verified via WKB / eikonal expansion; its eikonal limit recovers the g̃-Hamilton-Jacobi equation, not via operator substitution. (3) The Dirac operator is recovered as the local Clifford/tetrad representation in the isochronous background — it emerges in the limit where temporal shear Σμ and disformal coupling B (φ) are negligible. (4) Spin-1/2 is reinterpreted as temporal-orientation holonomy of the proper-time phase frame, and antiparticles as reversed proper-time orientation within the temporal-orientation bundle, eliminating the need for a macroscopic two-sheeted spacetime. (5) The spinor structure of relativistic quantum mechanics may be reinterpreted geometrically: Dirac's 1928 spinor encoded temporal-orientation holonomy without access to a dynamical proper-time geometry. These results recover standard relativistic quantum mechanics as the screened tangent-space limit of the TEP causal geometry, in the regime where the temporal field is frozen and locally constant over the interaction scale; the saturation scale ρT ≈ 20 g/cm³ is empirically calibrated in TEP-UCD (Paper 6). Keywords: Temporal Equivalence Principle, Temporal Shear, Temporal Topology, proper time, conformal metric, disformal metric, synchronization holonomy, clock-sector gravity, scalar-tensor theory, quantum foundations, Dirac equation, phase transport, spin, antimatter, geometric quantum mechanics Website: https: //mlsmawfield. com/tep/qfRepository: https: //github. com/matthewsmawfield/TEP-QF DOI: 10. 5281/zenodo. 20572697 Open Science Statement: This work is a preprint and is open to community review, ideas, and collaboration. All manuscripts and analysis code are open source. Feedback and contributions are welcome.
Matthew Lukin Smawfield (Fri,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: