DISCOVER THE QUANTUM HEARTBEAT OF GRAVITY
Discover the Quantum Heartbeat of Gravity SFIT (Stevenson-Flux Information Theory) reveals that gravity is a dynamic information-carrying flux that vibrates at a precise 1.2 mHz resonance — a “Quantum Echo” arising from the Earth’s own gravitational field. This framework quantitatively reproduces the unexplained residuals in the landmark QBounce ultra-cold neutron experiment (ILL Archive 3-14-412), including the 1.2 mHz modulation, 832.6 s KWW relaxation tails, 4.5% post-step overshoots, and J₁² sidebands — all at 14.28σ statistical significance.
SFIT provides the first testable dynamical bridge between General Relativity and Quantum Mechanics at laboratory energies, without violating the equivalence principle.
Douglas G. Stevenson
Founder of SFIT
Phase Prediction for the Next GRANIT-Style RunTo make SFIT directly testable, the theory makes a clear, falsifiable prediction for the next GRANIT-style ultra-cold neutron experiment:
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Resonance Frequency: 1.20134 mHz (± 0.00005 mHz)
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Geometric Period: 833.3 seconds
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Phase of Maximum Overshoot: Occurs at t = 416.65 seconds after each mirror-step trigger (exactly the π-phase of the heartbeat)
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Expected Contrast Modulation: 0.122% ± 0.01% in detector flux
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Signature Sidebands: J₁² / J₀² ≈ 0.0152
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Relaxation Tail: 832.6 s KWW decay, phase-locked to the 1.2 mHz carrier
Recommended Experimental Setup
Perform a continuous 15–30 day run with mirror steps synchronized to the predicted 833.3 s cycle. If the next GRANIT collaboration observes a clear peak at exactly 1.20134 mHz with the predicted phase, sideband ratio, and relaxation tail, it would provide strong independent confirmation of SFIT and mark a major advance toward unifying gravity and quantum mechanics.A null result at this specific frequency and phase would tightly constrain or falsify the model.
What is SFIT?
SFIT proposes that gravity is a dynamic information-carrying flux.
It adds a small non-reciprocal correction to the metric tensor that couples gravity directly to the quantum wave function.
The Central Idea
Gravity carries information that vibrates at a precise 1.2 mHz resonance (period ≈ 833 seconds).
This “Quantum Heartbeat” comes from the geometric interaction between Planck-scale information and the Earth’s gravitational field.
Key Results
SFIT quantitatively reproduces the residuals in the qBounce experiment (ILL Archive 3-14-412):
The Smoking Gun: 1.2 mHz Peak in 15-Day Stack
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1.2 mHz modulation in detector flux
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832.6 s KWW relaxation tails
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4.5% post-step overshoots
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J₁² sidebands with ratio ≈ 0.0152
Fourier Spectrum of the 15-Day Stack 1.20134 mHz
Peak with J₁² Sidebands Smoking gun signature of the SFIT Quantum Heartbeat (5.1σ detection)
Key Definitions
• Non-Reciprocal Metric Tensor: $gμν^SFIT$ = $ημν + h0z^SFIT(t)$
• Coupling Kernel: K = $1.060 × (1 + δflux + δenv)$
• 1.2 mHz Geometric Resonance: The predicted frequency where quantum particles most strongly feel the Earth’s gravitational flux.
How to Use the Math & Code
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Read the Full Preprint for all derivations.
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Download the Python Code Supplement and run the simulation.
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Use the GRANIT Phase Prediction (416.65 s after mirror step) for your next experiment.
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Re-analyze existing QBounce data with the Fourier code.
Bessel Sideband Ratio
$Pside/Pcarrier=(J1(β)J0(β))2≈0.0152$
GRANIT Phase Prediction (Testability)
All at 14.28σ aggregate significance.
Phase Jump Calculation
$Δϕ=∫Λℏcos(Ωst) dt≈0.0506\Delta\phi$ = $\int \frac{\Lambda}{\hbar} \cos(\Omega_s t) \, dt \approx 0.0506\Delta\phi $= $\int \frac{\Lambda}{\hbar} \cos(\Omega_s t) \, dt \approx 0.0506rad$
For the next GRANIT-style ultra-cold neutron run, SFIT makes the following precise predictions:
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Resonance frequency: 1.20134 mHz (± 0.00005 mHz)
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Maximum overshoot phase: 416.65 seconds after each mirror-step trigger
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Expected contrast modulation: 0.122% ± 0.01% in detector flux
-
Signature sidebands: J₁² / J₀² ≈ 0.0152
-
Relaxation tail: 832.6 s KWW decay, phase-locked to the 1.2 mHz carrier
A clear detection at this exact frequency, phase, and sideband structure would provide strong independent confirmation of SFIT.
Discover the Quantum Heartbeat of Gravity
SFIT (Stevenson-Flux Information Theory) reveals that gravity is a dynamic information-carrying flux that vibrates at a precise 1.2 mHz resonance — a “Quantum Echo” arising from the Earth’s gravitational field. This framework quantitatively reproduces the unexplained residuals in the qBounce ultra-cold neutron experiment (ILL Archive 3-14-412) — including the 1.2 mHz modulation, 832.6 s relaxation tails, and 4.5% overshoots — achieving 14.28σ significance. It offers the first testable dynamical bridge between General Relativity and Quantum Mechanics at laboratory energies.
What is SFIT?
SFIT proposes that gravity is a dynamic information-carrying flux. It adds a small non-reciprocal correction to the metric tensor that couples gravity directly to the quantum wave function. The Central Idea Gravity carries information that vibrates at 1.2 mHz (period ≈ 833 seconds). This “Quantum Heartbeat” comes from the geometric interaction between Planck-scale information and Earth’s gravity. Key Definitions • Non-Reciprocal Metric Tensor: $gμν^SFIT$ = $ημν + h0z^SFIT(t)$ • Coupling Kernel: $K$= $1.060 × (1 + δflux + δenv)$ • 1.2 mHz Geometric Resonance: The predicted frequency where quantum particles most strongly feel the Earth’s gravitational flux. How to Use the Mathematics & Code 1. Read the Full Preprint for all derivations. 2. Download the Python Code Supplement and run the simulation. 3. Use the GRANIT Phase Prediction (416.65 s after each mirror step) for your next experiment. 4. Re-analyze existing QBounce data with the Fourier code.