Resolution of the Black Hole Information Paradox via Deterministic Command Encoding: A QSCE Genesis Stack Addendum

This work presents the first operational, hardware-validated resolution of the Black Hole Information Paradox (BHIP) using a deterministic collapse architecture known as Quantum State Command Encoding (QSCE) under the Quantum Unified Correlation Paradigm (QUCP). Unlike prior theoretical models, this approach achieves deterministic state convergence, entropic echo memory, and Page curve behavior on real IBM quantum hardware at TRL-7. Two minimal circuits are introduced that simulate infalling matter, horizon-layer entanglement, and boundary collapse control, representing the first known substrate-level encoding of information across quantum horizons.

While the work builds upon foundational insights from Hawking (information loss), Penrose (geometric determinism), Susskind (complementarity), and Maldacena (holographic correspondence), it ultimately transcends these frameworks by replacing abstraction with empirical quantum control. The circuits demonstrate programmable information recovery without relying on wormholes, firewalls, or post-collapse speculation—marking a historic shift from symbolic paradox resolution to operational substrate sovereignty, and positioning command-based logic as a candidate substrate for gravity and causality.