Probabilistic theories: what is special about Quantum Mechanics?

TL;DR

This paper explores the foundational principles that uniquely characterize Quantum Mechanics among probabilistic theories, proposing operational postulates and analyzing their implications for the structure of quantum theory.

Contribution

It introduces two operational postulates, NSF and PFAITH, and demonstrates their implications for the mathematical structure of probabilistic theories, advancing understanding of quantum foundations.

Findings

All NSF-satisfying theories admit a C*-algebra representation.

Postulate PFAITH implies tensor-product structure and other quantum features.

The framework suggests a pathway to derive QM from operational principles.

Abstract

Quantum Mechanics (QM) is a very special probabilistic theory, yet we don't know which operational principles make it so. All axiomatization attempts suffer at least one postulate of a mathematical nature. Here I will analyze the possibility of deriving QM as the mathematical representation of a "fair operational framework", i.e. a set of rules which allows the experimenter to make predictions on future "events" on the basis of suitable "tests", e.g. without interference from uncontrollable sources. Two postulates need to be satisfied by any fair operational framework: NSF: "no-signaling from the future"--for the possibility of making predictions on the basis of past tests; PFAITH: "existence of a preparationally faithful state"--for the possibility of preparing any state and calibrating any test. I will show that all theories satisfying NSF admit a C*-algebra representation of events as linear transformations of effects. Based on a very general notion of dynamical independence, it is easy to see that all such probabilistic theories are "non-signaling without interaction" ("non-signaling" for short)--another requirement for a fair operational framework. Postulate PFAITH then implies the "local observability principle", the tensor-product structure for the linear spaces of states and effects, the impossibility of bit commitment and additional features, such an operational definition of transpose, a scalar product for effects, weak-selfduality of the theory, and more. Dual to Postulate PFAITH an analogous postulate for effects would give additional quantum features, such as teleportation. However, all possible consequences of these postulates still need to be investigated, and it is not clear yet if we can derive QM from the present postulates only. [CONTINUES on manuscript]