This article is currently under review in the journal ; Foundations of Physics This paper presents a formal mathematical investigation into the modification ofthe Lorentz factor through the integration of Boltzmann-derived statistical distributions within the high-energy limit of special relativity. We propose a conceptualbridge between the kinematic behavior of relativistic bodies and the stochasticnature of spacetime at the Planck scale, positing that the vacuum exhibits aneffective thermal character that regulates divergent physical quantities. By correlating the Unruh-Hawking temperature associated with Planckian accelerationsto the Gibbs factor, we derive a modified relativistic operator that introducesa deterministic damping mechanism for particles approaching the luminal limit.Unlike conventional doubly special relativity models which often employ heuristic regularizations to enforce an invariant energy scale, the present frameworksuggests that Lorentz invariance violation emerges naturally from the thermodynamic degrees of freedom inherent in the quantum manifold. The resultingmodified Hamiltonian leads to a phase transition where relativistic deformationsvanish asymptotically, causing physical observables such as energy and momentum to return to their rest-state eigenvalues at the velocity of light. We concludeby calculating the critical Lorentz threshold for a proton, demonstrating thatwhile the predicted deviations remain beyond the reach of current experimentaldetection, they provide a theoretically consistent resolution to the singularitiesof classical relativity through the lens of universal statistical regulation.
Said Enis Ersoy (Mon,) studied this question.