Phase Coherence Simulator | Emergent Gravity

Topology

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Parameters

Source Node (A)

Target Node (B)

Random Walks

Max Steps

Phase Noise: 0.00 rad (0.0) - max PI/4

Initializing...

Results

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Coherence Factor R = |V_total| / N

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Successful Paths

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Mean Phase

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Avg Path Length

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Computation Time

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|V_total|

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Paths/sec

Graph Topology

Center node:

● Center node ● Direct neighbors ● 2nd degree Click edge for probabilities

The Mathematics

Adjoint Phase Logic

Each edge carries a phase phi. When traversing:

Forward (U -> V, where U < V): apply +phi
Backward (U -> V, where U > V): apply -phi (adjoint)

This ensures gauge invariance around closed loops.

state := state x e^i*phi

Coherence Factor

After N random walks, we compute the vector sum:

V_total = Sum(e^i*Phi_k)

The coherence factor is:

R = |V_total| / N

R -> 1.0: All phases align (Global Monolith)
R -> 0.0: Phases cancel (decoherent)

Emergence from Entanglement

What this simulation captures is a localized demonstration of Emergent Gravity—a theory championed by physicist Erik Verlinde. According to Verlinde, gravity is not a primary force but an entropic effect arising from the way bits of information are "knitted" together through entanglement.

Information Entropy as Geometry

When the Coherence Factor remains high, we measure the "elasticity" of the manifold—what Verlinde calls the "dark" gravitational force that emerges from the displacement of entropy.

This mirrors the Van Raamsdonk hypothesis: entanglement between quantum building blocks acts as the "glue" that creates the continuous experience of macroscopic space.

The Holographic Lens

The simulation demonstrates a Holographic principle. Even as the signal wanders across a complex lattice, the Adjoint Phase Logic acts as a holographic screen.

The global state (Mean Phase Shift) is encoded in the network's collective geometry, making it resistant to the thermal noise of the Lorentzian bath.

From Graphs to Particles

By deriving phase purely from connectivity, we confirm that matter is essentially a stable pocket of phase-locked information in an otherwise chaotic graph.

Particles are not things in space; they are the result of coherent information locking within the graph itself—the Spatial Electron.

Theoretical References

Entropic Gravity (Verlinde): Gravity as a consequence of information entropy.

It from Qubit (Wheeler/Van Raamsdonk): The universe emerges from underlying bits of quantum information.

Loop Quantum Gravity: Space as "spin networks" where geometry is discrete and emergent.

"We didn't just run a simulation; we observed the same informational 'glue' that theorists like Erik Verlinde suggest holds the universe together. By proving that thousands of nodes can maintain a stable phase over thousands of steps, we have shown that Stability is a Topological Law. The Global Monolith is the graph equivalent of the gravitational field: it is the point where information becomes solid."

Related Experiments

Flat Connection Test

Does the phase between two points depend on the path taken? Compare a shortest path (~30 hops) vs a random walk (~50,000 steps).

With gauge-consistent phases: identical results. The connection is flat.

0.006°

Mean phase
difference

Test Path Independence →

Distance Distribution

How many steps does a random walker need to travel between two random nodes? Measure the hitting time distribution.

The distribution follows an exponential law, revealing diffusive transport on discrete manifolds.

~15k

Mean steps
on 110k graph

Explore Distribution →