Standard quantum mechanics is shown to produce definite outcomes and nonlocal correlations for entangled subsystems by extracting subsystem state vectors from one wavefunction.
Mechanism of wavefunction collapse in measurements of separated quantum subsystems
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abstract
The specific advance of this work is to propose a mechanism by which superpositions collapse during measurement of the separated subsystems of entangled quantum states. It is shown how the phase that locks together entangled states plays a special role in the measurement of isolated subsystems. This `contextual' phase is installed randomly into the entangled state, and decides the measurement outcomes for the subsystems by directing the collapse of each superposition to a particular classical outcome when a subsystem is measured. The measuring apparatus thus obtains a classical read-out of the quantum correlations embedded in an entangled state. More broadly, these results solidify the theory of measurement of quantum superpositions.
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quant-ph 1years
2026 1verdicts
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Collapse of the state vector and nonlocal correlations in quantum mechanics
Standard quantum mechanics is shown to produce definite outcomes and nonlocal correlations for entangled subsystems by extracting subsystem state vectors from one wavefunction.