Spin correlations in tt¯ production and decay at the LHC in QCD perturbation theory

In this work we consider the QCD predictions for spin correlations in tt production in hadronic collisions. In view of recent tensions between experimental data and theoretical calculations, it has been argued that one should include in the predictions also the effects of the production of the eta t, i.e. the pseudoscalar tt bound state, or alternatively the full effects of the non-relativistic dynamics of the tt pair near threshold. This implies the resummation of all corrections that scale like powers of alpha s/v (where v is the velocity of the top quark in the tt rest frame) which are dominated by values of v of order alpha s. In this work, we show that, since the observables that are usually considered for these studies are integrated cross sections up to a tt mass cut that is not small, it is possible to perform the calculation using perturbation theory, considering only the contributions that scale as the first few powers of alpha s/v. We examine the implications of our approach by computing corrections to nominal Monte Carlo results for correlation-sensitive observables, and compare them with available data, showing that the tension with data is no longer present.