The Second Law of Infodynamics and Its Gravitational Realization in SFIT pt 2

The second law of infodynamics, proposed by Melvin M. Vopson (AIP Advances, 2023), states that information entropy tends to remain constant or decrease over time — opposite to the classical second law of thermodynamics. Vopson argues this supports the simulated universe hypothesis.

SFIT extends these ideas into the gravitational domain. Gravity is described as a dynamic information-carrying flux vibrating at$ 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 is

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

This flux produces a non-reciprocal metric correction and drives KWW relaxation tails with τ≈$832.6 s  \tau \approx 832.6\,\rm s$ τ≈$832.6s$ and β=K=$1.060  \beta$ = K = $1.060 $β=K=$1.060$.

Derivation of the 11.42 Hz Mode The energy shift induced by the SFIT potential in the sub-femtovolt regime is$ ΔE$≈$4.72×10−14  \Delta E \approx 4.72 \times 10^{-14}$ $ΔE$≈$4.72×10−14 eV$. Using Planck’s constant $h$=$4.135667662×10−15$  $h$ = $4.135667662 \times 10^{-15}$$ h$=$4.135667662×10−15 eV·s$, the corresponding frequency is

$νsec$=$ΔEh$=$11.42 Hz.\nu_{\rm sec} $= $\frac{\Delta E}{h}$ =$11.42~\rm Hz.νsec$​=$hΔE$​=$11.42 Hz$.

This secondary mode may represent a higher harmonic or sampling rate of the neutron’s interaction with the informational flux.

Connection to Infodynamics and the Simulated Universe Vopson’s law suggests information entropy is minimized. In SFIT, the gravitational flux at 1.20134 mHz (with secondary sampling at 11.42 Hz) provides a physical mechanism for this minimization while producing measurable resonant effects. This is consistent with a simulated universe, where gravity could serve as an efficient information-processing substrate.

Future GRANIT experiments will test these predictions and further characterize the 11.42 Hz mode.

Figure Suggestion (add to your blog post):

Figure 1. Power Spectral Density (PSD) of the synthetic and qBounce data showing the primary 1.20134 mHz Quantum Heartbeat peak and the secondary 11.42 Hz mode. The inset highlights the phase-locked nature of the primary resonance.

Figure 2. KWW relaxation tail fit (τ≈$832.6  \tau \approx 832.6$ τ≈$832.6 s$, β=$1.060  \beta = 1.060$ β=$1.060$

) after mirror steps, demonstrating the memory kernel induced by the information flux.