Interpretation of Quantum Theory and Cosmology

• URL: http://arxiv.org/abs/2304.07095v1
• Date: Fri, 14 Apr 2023 12:32:30 GMT
• Title: Interpretation of Quantum Theory and Cosmology
• Authors: Giovanni M. Prosepri, Massimiliano Baldicchi
• Abstract summary: We reconsider the problem of the interpretation of the Quantum Theory (QT) in the perspective of the entire universe. For the Universe we adopt a variance of the LambdaCDM model with Omega=1, one single inflaton with an Higgs type potential, the initial time at t=minus infinite.
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• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: We reconsider the problem of the interpretation of the Quantum Theory (QT) in the perspective of the entire universe and of Bphr idea that the classical language is the language of our experience and QT acquires a meaning only with a reference to it. We distinguish a classical or macroscopic level, and a quantum or microscopic one that is perceived only through the modifications that it induces in the first. The macroscopic state of the universe is assumed to be specified by a set of variables, a classical energy momentum tensor and some conserved currents, which are supposed to have a well defined value across the entire space-time. To the energy-momentum tensor a classical metric is related by the Einstein equation. The quantum state and dynamics are expressed by the usual QT formalism in terms of a density operator and the ordinary quantum operators in Heisenberg picture. For the macroscopic variables a basic distribution of probability is postulated in terms of a density and the corresponding quantum operators, so in some way their evolution is driven by the underlying QT. Such postulate essentially replaces the usual elfadjoint operators correspondence. For the Universe we adopt a variance of the {\Lambda}CDM model with Omega=1, one single inflaton with an Higgs type potential, the initial time at t=minus infinite. The expectation values of all fundamental fields are supposed to vanish for time going to minus infinite. In the framework the scalar fluctuation in the Cosmic Microwave Background are correctly explained giving appropriate calue to the parameters in the potential. As in more conventional models the absence of the tensor fluctuations remains not understood, if even a quantum metric is introduced. This seems to suggest that Gravity is a pure classical phenomenon, what could be consistently accommodated in our formalism by an appropriate even if somewhat ad hoc assumption

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