Certified Quantumness via Single-Shot Temporal Measurements

TL;DR

This paper presents a single-shot, time-based proof of quantum contextuality that certifies quantumness without inequalities, using temporal measurements on a single particle to demonstrate fundamental quantum-classical conflicts.

Contribution

It introduces a novel temporal version of Peres's contextuality proof, enabling certification of quantumness through single-shot, time-separated measurements without inequalities.

Findings

Temporal measurements conflict with classical assumptions

Proof of quantumness is non-probabilistic and inequality-free

Results are experimentally verifiable with current technology

Abstract

Bell-Kochen-Specker theorem states that a non-contextual hidden-variable theory cannot completely reproduce the predictions of quantum mechanics. Asher Peres gave a remarkably simple proof of quantum contextuality in a four-dimensional Hilbert space of two spin-1/2 particles. Peres's argument is enormously simpler than that of Kochen and Specker. Peres contextuality demonstrates a logical contradiction between quantum mechanics and the noncontextual hidden variable models by showing an inconsistency when assigning noncontextual definite values to a certain set of quantum observables. In this work, we present a similar proof in time with a temporal version of the Peres-like argument. In analogy with the two-particle version of Peres's argument in the context of spin measurements at two different locations, we examine here single-particle spin measurements at two different times $t=t_1$ and $t=t_2$. We adopt three classical assumptions for time-separated measurements, which are demonstrated to conflict with quantum mechanical predictions. Consequently, we provide a non-probabilistic proof of certified quantumness in time, without relying on inequalities, demonstrating that our approach can certify the quantumness of a device through single-shot, time-separated measurements. Our results can be experimentally verified with the present quantum technology.