A Novel Solution of the Quantum Measurement Problem (2504.18561v1)

Abstract: In spite of the innumerable attempts to resolve the quantum measurement problem, almost since its beginning a century ago, a satisfactory solution still remains elusive. However, after the advent of quantum entanglement leading to environmental decoherence studies, a substantial leap forward has been achieved by Zurek and his associates. Their investigation has led to the existence of sturdy pointer states that survive decoherence leading to classicality although still remaining entangled with the environment and the apparatus states. But in order to avoid the inexplicable collapse postulate, Zurek invokes Everett's many world conjecture, which is not accepted by many experts. In this article, we present the observation of entanglement sudden death (ESD), demonstrating that disentanglement of the pointer states is caused by the quantum fluctuations of the electromagnetic field. We reveal that the decoherence between the pointer states and the environment is consistent with unitary evolution when the vacuum modes are included in the calculation, in analogy to the unitary evolution of the whole system in the spontaneous emission process. However, the ultimate state of the system is still subject to the totally unpredictable nature of individual quantum fluctuations, causing the stochastic appearance of an arbitrary classical state in von Neumann's collapse axiom even when the entire system evolves unitarily. Therefore, we suggest that an acceptable solution of the long standing measurement problem has finally been achieved.