Quantum Convergence Threshold (QCT): A First-Principles Framework for Informational Collapse.

Abstract

Gregory P. Capanda*

The Quantum Convergence Threshold (QCT) framework presents a deterministic, first-principles model in which wavefunction collapse arises as an informational convergence process rather than a stochastic or observer-dependent event. Collapse occurs when a system’s internal informational flux Λ(x,t) and temporal resolution Δt exceed its coherence-sustaining capacity Ω, modulated by a dimensionless awareness-threshold function Θ(t). The formal criterion Θ(t)·Δt·Λ/Ω ≥ 1 defines the transition point at which quantum superposition becomes informationally unsustainable, forcing a deterministic convergence to a single outcome. This replaces probabilistic postulates with a continuous, measurable buildup of informational density that can, in principle, be monitored experimentally.

QCT introduces explicit, physically motivated terms — informational flux density (Λ), coherence pressure (Ω), and the awareness threshold function (Θ) — into the Schrödinger framework, producing a modified evolution equation that preserves unitarity until convergence becomes unavoidable. The theory predicts measurable threshold signatures in interferometric visibility, hysteresis effects under repeated weak measurement, and scaling relationships between collapse time, decoherence rate, and informational load. Beyond addressing the measurement problem, QCT connects quantum foundations with quantum information theory and thermodynamics, suggesting a unified informational ontology for the transition from quantum potentiality to classical actuality. Its implications extend to quantum computing, decoherence control, and the emergence of classicality itself, providing a rigorous platform for experimental falsification and theoretical expansion.

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