This paper declares that the measurement problem of quantum mechanics has been resolved geometrically. In standard quantum mechanics, wavefunction collapse is a process that is assumed, acknowledged, but never explained. Based on the SGCU framework, this paper demonstrates that measurement is not a mysterious event, but an irreversible topological locking between Ψ defects and the macroscopic Ψ background. Core revolutionary claims: · Superposition is not a physical state, but an unfrozen topological possibility. It is not "two worlds existing simultaneously", but a defect's topological degrees of freedom that have yet to be locked by the background. · Entanglement is not spooky action at a distance, but a non-local topological correlation between two defects mediated by the Ψ field background. It is a geometric constraint, not signal transmission. · Measurement is not choice, but locking. Wavefunction collapse is not the collapse of probability, but the process by which the microscopic defect's topological freedom loses its independence in the macroscopic background. · Quantum mechanics is not a fundamental theory. It is an effective description of the topological defects of Ψ. Its "mystery" arises solely from our neglect of the Ψ field. This paper completes the leap from 2.4 (black hole memory) to 2.5 (quantum measurement): macroscopically, black holes transmit information across cycles; microscopically, measurement extracts information from defects. Both are unified through the same topological structure of Ψ. Quantum measurement is no longer a mystery. It is geometry.
Yida Huo (Wed,) studied this question.
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