Measuring a Quantum Measure Exceeding Unity

TL;DR

This paper experimentally demonstrates a quantum measure exceeding unity, illustrating non-classical interference effects with a measured value of 1.172, close to the theoretical 5/4, using an optical setup.

Contribution

The first experimental measurement of a quantum measure exceeding one, providing operational insight into quantum interference effects in a photonic experiment.

Findings

Measured quantum measure μ(E)=1.172, close to the theoretical 5/4.

Quantum measure exceeds classical probability maximum of 1 by 13 standard deviations.

Experimental setup links detector probability to quantum measure via calibration.

Abstract

The history based formalism known as Quantum Measure Theory (QMT) generalizes the concept of probability-measure so as to incorporate quantum interference. The resulting \textit{quantum measure} $\mu$ is defined for arbitrary events (sets of histories), not just for observables at a fixed moment of time. Thanks to interference effects, $\mu$ can exceed unity, exhibiting its non-classical nature in a particularly striking manner. Here, in an optical experiment, we illustrate an ancilla based filtering scheme that gives operational meaning to the quantum measure. For a specific photonic event $E$, we report a measured value of $\mu(E)=1.172$, which within errors agrees with the theoretical value of $5/4$, while exceeding the maximum value permissible for a classical probability (namely $1$) by about $13$ $\sigma$-equivalent (percentile-based) units. The directly observed quantity is an ordinary detector probability $p_D\le 1$ (or, with laser light, an equivalent power ratio); the value $\mu(E)>1$ is inferred via the calibrated relation $\mu(E)=2p_D$ for our filter. If an unconventional theoretical concept is to play a role in meeting the foundational challenges of quantum theory, it seems important to bring it into contact with experiment as much as possible. Our experiment does this for the quantum measure.