A mathematical model for measurement

TL;DR

This paper introduces a new mathematical model for quantum measurements using advanced operator algebra techniques, where measurement outcomes are represented as superpositions of phases with probabilistic weights, emphasizing state reduction as a fundamental process.

Contribution

It develops a novel quantum measurement model employing unital separable non-type I nuclear simple C*-algebras and endomorphisms, providing a new perspective on wave function collapse.

Findings

Measurement modeled as superposition of phases with weights

State reduction is a primary event in the model

Probabilistic selection of phases mimics wave function collapse

Abstract

We will give a new model for measurements of a quantum system such that the measuring apparatuses are described by a unital separable non-type I nuclear simple C$^*$-algebra equipped with certain unital endomorphisms and pure states. An interaction between the quantum system and the apparatus is specified by a unitary associated with the combined system as before. Magnifying to the classical level some aspects of the quantum system so captured in the apparatus is explicitly done by applying the endomorphism; then the resulting state is the superposition of {\em phases} with weights. Nature will then choose each phase according to the probability prescribed by the weights just as does one when multiple phases appear as in phase transition. Thus in our model state-reduction (or collapse of the wave function) is a primary event; whether this corresponds to the measurement of an observable or which one if it does is another matter.