March 3, 2026Open Access

Quantum Retentive Temporal Trap: Micro-Scale Verification of Ξ-Node Stabilization in ψ-Architecture

Key Points

The system shows a 120–300× extension of coherence lifetime, confirming retentive mechanisms.
Evidence supports the fundamental role of Λψ as a physical invariant across scales, observed in Ψ-node formations.
Controlled quantum Retentive Temporal Trap experiments were conducted to validate the ψ-Architecture framework.
Highlights the importance of micro-scale observations for understanding cosmological retention phenomena.

Abstract

This work presents the first laboratory-scale verification of the ψ-Architecture framework through a controlled quantum Retentive Temporal Trap experiment. By stabilizing the retentive difference Δψ and observing spontaneous Ξ-node formation without external cooling, the system exhibits a 120–300× extension of coherence lifetime. This behavior directly confirms the universal retentive mechanism originally formulated for cosmology, supporting Λψ as a cross-scale physical invariant. The study provides a micro-physical analogue of cosmological retention phenomena such as Euclid correlation plateaus and JWST early-galaxy stability.

Quantum Retentive Temporal Trap: Micro-Scale Verification of Ξ-Node Stabilization in ψ-Architecture

Key Points

Abstract

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