Optimizing Entanglement and Bell Inequality Violation in Top Anti-Top Events

TL;DR

This paper introduces an optimal basis for analyzing entanglement and Bell inequality violation in top anti-top quark events, enhancing measurement sensitivity in collider experiments.

Contribution

It analytically identifies the basis that maximizes spin correlations, entanglement, and Bell violation, applicable across different collider energies and systems.

Findings

Optimal basis aligns with the fixed beam near threshold

Approaches the helicity basis far above threshold

Enhances detection sensitivity for Bell violation in collider data

Abstract

A top quark and an anti-top quark produced together at colliders have correlated spins. These spins constitute a quantum state that can exhibit entanglement and violate Bell's inequality. In realistic collider experiments, most analyses allow the axes, as well the Lorentz frame to vary event-by-event, thus introducing a dependence on the choice of event-dependent basis leading us to adopt "fictitious states," rather than genuine quantum states. The basis dependence of fictitious states allows for an optimization procedure, which makes the usage of fictitious states advantageous in measuring entanglement and Bell inequality violation. In this work, we show analytically that the basis which diagonalizes the spin-spin correlations is optimal for maximizing spin correlations, entanglement, and Bell inequality violation. We show that the optimal basis is approximately the same as the fixed beam basis (or the rotated beam basis) near the $t\bar t$ production threshold, while it approaches the helicity basis far above threshold. Using this basis, we present the sensitivity for entanglement and Bell inequality violation in $t\bar t$ events at the LHC and a future $e^+e^-$ collider. Since observing Bell inequality violation appears to be quite challenging experimentally, and requires a large dataset in collider experiments, choosing the optimal basis is crucially important to observe Bell inequality violation. Our method and general approach are equally applicable to other systems beyond $t \bar t$, including interactions beyond the Standard Model.