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Entanglement and the Measurement Problem

Art Hobson

2022Quantum Engineering17 citationsDOIOpen Access PDF

Abstract

The entangled “measurement state” (MS), predicted by von Neumann to arise during quantum measurement, seems to display paradoxical properties such as multiple macroscopic outcomes. But analysis of interferometry experiments using entangled photon pairs shows that entangled states differ surprisingly from simple superposition states. Based on standard quantum theory, this paper shows that the MS (i) does not represent multiple detector readings but instead represents nonparadoxical multiple statistical correlations between system states and detector readings, (ii) implies that exactly one outcome actually occurs, and (iii) implies that when one outcome occurs, the other possible outcomes simultaneously collapse nonlocally. Point (iii) resolves an issue first raised in 1927 by Einstein who demonstrated that quantum theory requires instantaneous state collapse. This conundrum’s resolution requires nonlocal correlations, which from today’s perspective suggests the MS should be an entangled state. Thus, contrary to previous presumed proofs of the measurement problem’s insolubility, we find the MS to be the collapsed state and just what we expect upon measurement.

Topics & Concepts

Quantum entanglementPhysicsSuperposition principleQuantum mechanicsVon Neumann architectureQuantum nonlocalityMeasurement problemOutcome (game theory)State (computer science)Photon entanglementQuantumTheoretical physicsQuantum stateStatistical physicsQuantum metrologyPhotonQuantum discordComputer scienceMathematicsMathematical economicsAlgorithmOperating systemQuantum Mechanics and ApplicationsQuantum Information and CryptographyAdvanced Thermodynamics and Statistical Mechanics
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