Logos UMST-G: Informational Gravity and the Quantum Nature of Entropy

We present a theoretical model in which gravitational interaction is supplemented bya dynamic scalar field associated with entropic processes. This field can influence thepropagation of gravitational waves, leading to the emergence of additional (scalar) modes,and affect the dynamics of astrophysical objects.Recent astrophysical observations have provided new data that may indicate thepresence of an additional contribution to the gravitational interaction. Within thismodel, an analysis of gravitational wave events GW150914, GW170814, GW190521,GW200129, and GW200220 was carried out, revealing stable spectral features corresponding to the predicted frequency ratio between scalar and tensor modes (0.67–0.73).Bayesian analysis showed a high level of statistical confidence (Bayes factor > 800),making the identified signatures significant for further study. The Prony method, usedor spectral decomposition of signals, confirmed the presence of additional componentsnot described by standard General Relativity.Furthermore, the analysis of galactic rotation curves shows that accounting for additional effects related to entropy distribution can reduce the discrepancies between observedvelocities and predictions of Newtonian dynamics.In this work, we examine in detail the theoretical foundations of the proposed model,provide quantitative predictions, and discuss possible physical mechanisms. In subsequentsections, we present a complete analysis of the experimental data obtained, thoroughlyexamining the methods used, their limitations, and prospects for further research.