Klein--Gordon Dynamics from Intrinsic Phase Periodicity

This work develops a phase-based formulation of relativistic wave dynamics, demonstrating that the Klein--Gordon equation emerges naturally from the foundational assumption of intrinsic phase periodicity in material fields. Mapping the phase directly onto the classical action, we postulate that localized excitations possess an invariant rest-frame oscillation governed by a proper frequency $ω_0$. This physical condition establishes an operational mass-frequency relation, $m = \hbar ω_0 / c^2$, without requiring rest energy as an independent, axiomatic input. We show that the Klein--Gordon equation arises as the minimal local, linear, Lorentz-invariant field equation compatible with this internal phase structure. Within this framework, mass acts as an intrinsic frequency scale governing wave propagation, and relativistic kinematics is fully recovered as a structural consequence of phase coherence. This approach provides a unified wave-mechanical interpretation where particle dynamics maps onto the group velocity of dispersive wave packets, offering an intuitive account of free propagation, dispersion, and tunneling across potential barriers.

Source: arXiv:2606.25929v1 - http://arxiv.org/abs/2606.25929v1 PDF: https://arxiv.org/pdf/2606.25929v1 Original Link: http://arxiv.org/abs/2606.25929v1