"The Second Law of Infodynamics and Its Connection to SFIT: Coupling Constant, Informational Entropy, and Gravitational Flux"

The second law of infodynamics, proposed by Melvin Vopson, states that information entropy in physical systems tends to remain constant or decrease over time — opposite to the second law of thermodynamics.

SFIT extends this idea into the gravitational domain. We propose that gravity acts as a dynamic information-carrying flux vibrating at the geometric resonance frequency $νres$=$1.20134 mHz  \nu_{\rm res} $= $1.20134\,\rm mHz$ $νres​$=$1.20134mHz$, governed by the coupling kernel K=1.060  K = 1.060 K=1.060.

The effective potential takes the form

$VSFIT(z,t)=mgz[1+KzRERe⁡(cos⁡(2πνrest))].V_{\rm SFIT}(z,t)$ = $m g z \left[ 1 + K \frac{z}{R_E} \operatorname{Re}\left(\cos(2\pi \nu_{\rm res} t)\right) \right].VSFIT​(z,t)$=$mgz[1+KRE​z​Re(cos(2πνres​t))]$.

This flux introduces an active dampening field and entropic force that drive the observed KWW relaxation tails (τ≈$832.6 s  \tau \approx 832.6\,\rm s$ τ≈$832.6s$, β=K=$1.060  \beta $= K = $1.060 $β=K=$1.060$) in ultra-cold neutron experiments.

A secondary feature near 11.42 Hz may represent a higher harmonic or mixing product. Stability analysis shows the primary 1.20134 mHz signal remains robust.

These results suggest SFIT provides a gravitational realization of infodynamic principles, with potential implications for the simulated universe hypothesis.

Reference to Vopson's AIP Advances paper The second law of infodynamics and its implications for the simulated universe hypothesis | AIP Advances | AIP Publishing