Empirical Testing: What Novel Predictions Does This Make?

Empirical Testing: What Novel Predictions Does This Make?

If we replace spacetime with process constraints, this should lead to testable predictions that distinguish our model from classical General Relativity (GR) and Quantum Mechanics (QM).

1. Quantum Gravity: No Singularities, Only Process Limits

• Prediction: Black holes do not contain singularities. Instead, process instantiation reaches a limit, leading to an effectively “frozen” region rather than an infinitely dense point.
• How to test: Look for deviations in Hawking radiation spectra that signal a transition from high-density process constraints rather than a singularity.

Big Bang Alternative:

• Prediction: The Big Bang was not a singularity but a process constraint limit—meaning we should observe a smooth transition instead of a breakdown at $\mathrm{<i>t </i>}= 0$.
• How to test: Future cosmic microwave background (CMB) observations might detect residual signatures from a non-singular quantum gravity regime.

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2. Gravitational Time Dilation Without Curved Spacetime

• Prediction: Instead of spacetime warping, gravitational effects result from constraints on process instantiation. Time dilation near massive objects should be slightly different from GR predictions.
• How to test: Atomic clock experiments in stronger gravitational fields might reveal a deviation from GR’s predictions at extreme precision levels.

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3. Entanglement as Joint Process Instantiation, Not Faster-Than-Light Information Transfer

• Prediction: If entangled particles represent jointly constrained process instantiations, then modifying one should have no causal effect on the other—it should only affect what information we can infer.
• How to test: Modify one half of an entangled pair’s quantum state while shielding the other completely from any interaction. If the correlation persists without causation, this supports our model.

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4. The Nature of Dark Matter & Dark Energy as Process Constraints

• Prediction: Dark matter and dark energy effects result from inhomogeneous process instantiation constraints, rather than unseen particles or exotic fields.
• How to test: If dark matter is not made of particles, but instead an effect of process constraints, then direct detection experiments should fail, and alternative gravitational lensing patterns might emerge.