How quantum paradoxes originate from the non-classical statistics of physical properties related to each other by half-periodic transformations

TL;DR

This paper explains how quantum paradoxes arise from non-classical, complex-valued probabilities linked to transformations with phases of Pi, revealing fundamental links between quantum statistics and dynamics.

Contribution

It demonstrates that half-periodic transformations inherently lead to negative probabilities, clarifying the origin of quantum paradoxes from a fundamental perspective.

Findings

Negative probabilities emerge from half-periodic transformations.

Quantum paradoxes are rooted in the relation between statistics and dynamics.

Complex quasi-probabilities encode non-commuting property relations.

Abstract

Quantum paradoxes show that quantum statistics can exceed the limits of positive joint probabilities for physical properties that cannot be measured jointly. It is therefore impossible to describe the relations between the different physical properties of a quantum system by assigning joint realities to their observable values. Instead, recent experimental results obtained by weak measurements suggest that non-classical correlations could be expressed by complex valued quasi-probabilities, where the phases of the complex probabilities express the action of transformations between the non-commuting properties (H. F. Hofmann, New J. Phys. 13, 103009 (2011)). In these relations, negative probabilities necessarily emerge whenever the physical properties involved are related to each other by half-periodic transformations, since such transformations are characterized by action phases of Pi in their complex probabilities. It is therefore possible to trace the failure of realist assumptions back to a fundamental and universally valid relation between statistics and dynamics that associates half-periodic transformations with negative probabilities.