ABSTRACT
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Entanglement phenomena offer fine, didactic examples that demonstrate the application of quantum trajectories. Quantum entanglement phenomena are tractable to the quantum trajectory representation. Quantum trajectories render insight into entanglement phenomena of quantum systems. Entanglement is one of the prime features that distinguishes quantum mechanics from classical mechanics. Entanglement implies nonlocality as confirmed by the Aspect experiments [1-3]. Entangled quantum systems have nonclassical correlations that manifest nonlocal behavior for the system. The quantum trajectory representation can describe how entanglement induces nonlocality [4]. Within the foundations of quantum mechanics, a quantum trajectory representation of entangled systems is the key to resolving the nonintuitive behavior of wave packet spreading [4], the which-way paradox of the double-slit experiment [5], and the Einstein-Podolsky-Rosen (EPR) paradox [6].
