Quantum SMEFT tomography: Top quark pair production at the LHC

Quantum information observables, such as entanglement measures, provide a powerful way to characterize the properties of quantum states. We propose to use them to probe the structure of fundamental interactions and to search for new physics at high energy. Inspired by recent proposals to measure entanglement of top quark pairs produced at the LHC, we examine how higher-dimensional operators in the framework of the Standard Model effective field theory modify the Standard Model expectations. We explore two regions of interest in the phase space where the Standard Model produces maximally entangled states: at threshold and in the high-energy limit. We unveil a nontrivial pattern of effects, which depend on the initial state partons, q (q) over bar or gg, on whether only linear or up to quadratic Standard Model effective field theory contributions are included, and on the phase space region. In general, we find that higher-dimensional effects lower the entanglement predicted in the Standard Model.

Automated summary

This study utilizes quantum information observables to probe the structure of fundamental interactions and search for new high energy physics. By investigating the effects of higher-dimensional operators in the Standard Model effective field theory on the Standard Model expectations, we find that higher-dimensional effects decrease the entanglement predicted in the Standard Model.