Energy-time uncertainty relation from entropy measures

TL;DR

This paper derives a generalized energy-time uncertainty relation using non-extensive entropy measures, revealing quantum gravity effects on spacetime fluctuations, black hole radiation, and fundamental limits at the Planck scale.

Contribution

It extends previous work by connecting non-extensive entropies to a generalized energy-time uncertainty relation, highlighting quantum gravity implications.

Findings

Modified dispersion relations consistent with quantum gravity

Black hole temperature corrections due to non-extensive spacetime behavior

Predicted maximum energy uncertainty and minimum time interval at Planck scale

Abstract

In a previous study, it was shown that the Generalized Uncertainty Principle (GUP) can be derived from non-extensive entropies, particularly those depending only on the probability, denoted as $S_\pm$ in the literature. This finding reveals an intriguing connection between non-extensive statistics and quantum gravity. In the present work, we extend our previous result and derive a generalized energy-time uncertainty relation based on a measure of non-extensive entropies. Consequently, the dispersion relation undergoes modifications consistent with those obtained in other approaches to quantum gravity. We interpret these modifications as evidence of the non-extensive behavior of spacetime fluctuations at scales close to the Planck scale. While these effects are significant in this regime, they become negligible in the classical one, i.e. at low energies where the spacetime is smooth. As a consequence of the non-extensive behavior exhibited by spacetime at very small scales, the black hole radiation temperature undergoes quantum-level corrections, increasing in the case of \( S_{-} \) and decreasing for the case of \( S_{+} \). Moreover, the modified uncertainty relation derived here predicts a maximum uncertainty in energy, of the order of Planck energy, and a minimum time interval, of the order of the Planck time, offering new insights into the fundamental structure of spacetime in the quantum regime.