Statistical Benchmarking of Scalable Photonic Quantum Systems

TL;DR

This paper demonstrates a scalable photonic quantum system capable of generating, distributing, and analyzing complex multi-photon quantum correlations across many modes, verified through high-order nonclassicality tests.

Contribution

It introduces a high-performance, scalable photonic framework with adaptive time-bin analysis and advanced detectors, enabling verification of high-order quantum correlations in large systems.

Findings

Produced around ten photons distributed over 64 modes

Verified nonclassical correlations up to the 128th order

Achieved statistical significance of up to 20 standard deviations

Abstract

Targeting at the realization of scalable photonic quantum technologies, the generation of many photons, their propagation in large optical networks, and a subsequent detection and analysis of sophisticated quantum correlations are essential for the understanding of macroscopic quantum systems. In this experimental contribution, we explore the joint operation of all mentioned ingredients. We benchmark our time-multiplexing framework that includes a high-performance source of multiphoton states and a large multiplexing network, together with unique detectors with high photon-number resolution, readily available for distributing quantum light and measuring complex quantum correlations. Using an adaptive approach that employs flexible time bins, rather than static ones, we successfully verify high-order nonclassical correlations of many photons distributed over many modes. By exploiting the symmetry of our system and using powerful analysis tools, we can analyze correlations that would be inaccessible by classical means otherwise. In particular, we produce on the order of ten photons and distribute them over 64 modes. Nonclassicality is verified with correlation functions up to the 128th order and statistical significances of up to 20 standard deviations.