Towards NNLO QCD predictions for off-shell top-quark pair production and decays

TL;DR

This paper presents a comprehensive calculation of NNLO QCD corrections to off-shell top-quark pair production and decay at the LHC, including validation of methods and estimation of uncertainties.

Contribution

It introduces an exact NNLO QCD calculation for off-shell top-quark pair production with leptonic decays, extending previous NLO results and validating approximation techniques.

Findings

NNLO corrections increase the cross section by about 11%.

The double-pole approximation performs well at both inclusive and differential levels.

Perturbative uncertainties are estimated below 2%, smaller than residual uncertainties.

Abstract

We consider QCD radiative corrections to $W^+W^-b {\bar b}$ production with leptonic decays and massive bottom quarks at the LHC. We perform an exact next-to-leading order (NLO) calculation within the $q_T$-subtraction formalism and validate it against an independent computation in the dipole subtraction scheme. Non-resonant and off-shell effects related to the top quarks and the leptonic decays of the $W^\pm$ bosons are consistently included. We also consider the approximation in which the real-emission contribution is computed exactly while the virtual is evaluated in the double-pole approximation (DPA), which formally requires the inclusion of both factorisable and non-factorisable corrections. We evaluate such contributions and show that the DPA performs remarkably well at both the inclusive and differential levels. We then extend our calculation to the next-to-next-to-leading order (NNLO). All tree-level and one-loop amplitudes are evaluated exactly, while the missing two-loop virtual contribution is estimated using the DPA. The factorisable two-loop corrections are explicitly computed by relying on available results for the polarised two-loop on-shell top-quark pair production amplitudes and the corresponding top-quark decays. The non-factorisable contributions are inferred by exploiting the cancellation of logarithmic singularities in the $\Gamma_t\to 0$ limit through an on-shell matching procedure. The NNLO corrections for the inclusive cross section are found to increase the NLO prediction by approximately $11\%$, with a numerical uncertainty that is conservatively estimated to be below the $2\%$ level $\unicode{x2013}$ significantly smaller than the $5\%$ residual perturbative uncertainties.