Characterizing quantum correlations and quantum teleportation in gg tt and qq tt processes under noisy channels

Abstract

The measurement of top-quark spin correlations provides a key tool for probing its interactions with high precision. Owing to its extremely short lifetime (τ 10-25 s), the top quark preserves its spin polarization information, making the tt system an ideal framework for investigating quantum correlations in high-energy physics. In this work, we analyze quantum correlations in tt pairs produced in QCD using several quantum information-theoretic measures, including Bell nonlocality, quantum steering, concurrence, and geometric quantum discord. Their dependence on kinematic variables is examined in both the gg tt and qq tt channels, with convergence toward the gg tt dominated regime in the ultra-relativistic limit (β = 1). We also investigate the effect of three effective decoherence channels (AD, PD, and PF). The AD and PD channels lead to a monotonic degradation of correlations as the decoherence parameter p increases, while the PF channel exhibits a symmetric behavior around p=1/2. The impact of these channels on quantum teleportation is analyzed, showing that it remains above the classical threshold of 2/3 even in the presence of noise. These results indicate that certain quantum resources can persist despite decoherence, opening new perspectives at the interface of quantum information and particle physics.