Mass-Dependent Temporal Behavior and Emergent Transient Wormhole Geometry in a Phenomenological Quantum Interpretation

The influence of particle-associated spacetime curvature on particle dynamics weakens at smaller particle mass scales, leading to an acceleration of effective state evolution characterized by T_eff, which is taken to be bounded by the Planck time as a theoretical lower limit within this framework. At sufficiently low masses, the effect of particle-bound transient wormholes becomes significant, offering a geometric interpretation of quantum nonlocality, preventing further meaningful subdivision of particles.

Wormhole influence increases as particle mass decreases, while classical particle-associated curvature increases with mass, representing complementary aspects of the same physical transition, with a crossover region determining which influence dominates. For particles with masses below this region, particle-bound transient wormhole effects emerge progressively and the influence of particle-associated curvature is correspondingly subdued; above the region, the reverse holds, with curvature becoming dominant and wormhole effects diminishing.

Extended version with illustrations available at: https://researchlogic.org