Disentangling new physics with quantum entanglement in $t\bar{t}$ production at future lepton colliders

TL;DR

This paper explores how quantum entanglement and Bell inequalities in top-antitop production at future lepton colliders can reveal new physics beyond the Standard Model, including extra particles and dimensions.

Contribution

It introduces quantum-information observables as novel tools to detect and distinguish various extensions of the Standard Model in collider experiments.

Findings

Entanglement is reduced in scalar mediator scenarios compared to the SM.

Significant deviations in entanglement and Bell parameters occur in $U(1)_{B-L}$ and Randall-Sundrum models.

Quantum-information observables are sensitive probes of new neutral interactions and extra-dimensional effects.

Abstract

We investigate quantum entanglement and Bell-inequality violation in top-antitop pair production at future lepton colliders such as the International Linear Collider (ILC) and multi-TeV muon colliders. Within the Standard Model (SM), the process proceeds through $s$-channel $\gamma$ and $Z$ exchange and exhibits characteristic spin-correlation patterns that encode a non-trivial amount of entanglement. We then examine how these features are modified in several well-motivated extensions of the SM:(i) a neutral scalar mediator that couples to charged leptons and top quarks via Yukawa interactions and contributes as an additional $s$-channel exchange; (ii) the minimal gauged $U(1)_{B-L}$ model, which introduces a new neutral gauge boson $Z'$ coupling vectorially to SM fermions; and (iii) a Randall-Sundrum scenario, in which the exchange of massive Kaluza-Klein gravitons arising from a warped extra dimension induces additional spin-dependent interactions. For all cases, we evaluate quantum-information observables, including the entanglement marker, the concurrence, and the maximal Clauser-Horne-Shimony-Holt parameter, and study their dependence on the center-of-mass energy, scattering angle, and model parameters. We find that, relative to the SM expectation, the entanglement is typically reduced in the scalar-mediator scenario, while sizable deviations can arise in the $U(1)_{B-L}$ and Randall-Sundrum cases for phenomenologically relevant regions of parameter space. These results demonstrate the potential of quantum-information observables as sensitive probes of new neutral interactions and extra-dimensional dynamics in future lepton colliders.