Experimental test of Tsirelson's bound with a single photonic qubit

TL;DR

This paper experimentally tests Tsirelson's bound using a single photonic qubit, demonstrating quantum advantage in the CHSH game and exploring the limits of quantum correlations.

Contribution

It provides the first experimental verification of Tsirelson's bound with a single photonic qubit, advancing understanding of quantum nonlocality.

Findings

Successfully demonstrated quantum advantage in the CHSH game with a single photon

Confirmed Tsirelson's bound experimentally in a photonic system

Explored the theoretical limits of quantum correlations without signaling

Abstract

For many protocols, quantum strategies have advantages compared with their classical counter-partners, and these advantages have attracted many interests and applications. One of the famous examples is the Clauser-Horne-Shimony-Holt (CHSH) game, which recasts Bell's theorem~\cite{2} into the framework of a game. In the CHSH game, two space-like separated players, Alice and Bob are each assigned a classical bit $a$ and $b$ respectively. Then they return bits $x$ and $y$ according to some pre-agreed strategies. They will win the game when $x\oplus y= a\cdot b$. In the game, if the players use the classical strategies, the optimal success probability $w(\text{CHSH})=0.75$.However, if they add some quantum resources, the success probability will increase and up to maximal value $cos^2(\pi/8)$, which is know as the Tsirelson's bound. Moreover, Popescu and Rohrlich noted that the perfect success probability $1$ can also be achieved in a more general theory without violating the no-signaling assumption