Quantum Coherence & Memory

In HDIF, quantum randomness emerges when curvature memory becomes incomplete. This provides a geometric explanation for quantum decoherence: the diffusion of memory across the interface field. This experiment explores whether coherence decay in oscillators, qubits, and photonic systems aligns with HDIF’s predicted memory-kernel behavior.

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Why It Matters:

If coherence loss can be mapped to memory-kernel dynamics, it could redefine our understanding of decoherence and suggest new pathways for stabilizing quantum information systems.

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Methods

Quantum oscillators, superconducting qubits, or photonic modes are monitored over time to track coherence decay. We fit decoherence curves to HDIF-inspired memory kernels           , comparing the predicted diffusion of geometric memory to observed collapse of superposition states. Experimental control over environmental noise allows isolation of memory-based contributions.

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Predicted Signatures

• Decoherence curves following HDIF memory-kernel profiles rather than exponential or Gaussian decay

• Frequency-dependent coherence loss matching curvature-memory diffusion

• Longer-lived or shorter-lived coherence depending on engineered interface feedback

• Distinct transitions from coherent to incoherent states correlated with predicted memory thresholds