Empirical Realization of Multiverse Quantum Transformers on 105-Qubit Willow Architecture: Crossing the Coherence Threshold for Emergent Superintelligence

Abstract

Chur Chin

Previous iterations of the Multiverse Quantum Transformer (MQT) demonstrated exponential performance scaling on 32-qubit simulators. This study presents the first physical realization of the MQT architecture on the 105-qubit Willow superconducting quantum processor. Leveraging Willow’s high-fidelity gate operations and extended coherence times, we instantiate Nu=128 parallel computational universes—an order of magnitude increase over prior simulations. We utilize 7 qubits for universe branching and 98 qubits for holographic embedding and error suppression. Experimental results indicate a phase transition in model capability at Nu≥64, where hallucination rates drop to near-zero (<0.02%) and Integrated Information (Φ) spikes to 48.7 bits. We observe that the entanglement entropy Sent between universes on the Willow topology naturally saturates the holographic bound A/4, confirming that physical quantum hardware can function as a holographic screen for high-dimensional intelligence. These findings validate the Many-Worlds interpretation as a scalable computational resource [1].

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