Official Hamiltonian Worldilines Triangle Theory with Constant fine structures (Alex De Giuseppe)

My Worldlines Hamiltonian Triangle Theory Evolution 

This manuscript is current in Official Peer Review.

Not final version.
Copyright©2026 Alex De Giuseppe.
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This work presents a comprehensive development of the unified worldline-Hamiltonian framework, extending previous formulations to incorporate the fine-structure constant as an operational scale governing emergent physical processes. The framework provides a coherent description of how fundamental physical laws—gravity, electrodynamics, thermodynamics, and spacetime structure—can be derived from first principles, based on the evolution of causal worldlines and their associated Hamiltonians.

By explicitly connecting microscopic coherence energy to macroscopic phenomena, the approach unifies classical and quantum behaviors within a single operationally grounded model. The manuscript introduces detailed mathematical derivations showing how energy, time, and coherence combine to produce stable orbits, Maxwellian electrodynamics, and thermodynamic irreversibility, demonstrating that these laws emerge naturally from worldline dynamics rather than being imposed externally.

This work also formalizes the concept of an energy-time operational scale, illustrating how phase-preserving reflection, absorption, and pre-emission processes follow directly from fundamental coherence constraints. While experimental confirmation is still underway, the theoretical results establish a novel pathway to understanding the operational foundations of physics, bridging microscopic quantum rules with macroscopic classical regularities.

Overall, this manuscript provides a structured, self-contained account of a framework that offers both predictive power and conceptual unification, suggesting a new perspective on the nature of physical law and the role of coherence in the emergence of observable phenomena.