Journal of High Energy Physics (Mar 2023)
Collinear functions for QCD resummations
Abstract
Abstract The singular behaviour of QCD squared amplitudes in the collinear limit is factorized and controlled by splitting kernels with a process-independent structure. We use these kernels to define collinear functions that can be used in QCD resummation formulae of hard-scattering observables. Different collinear functions are obtained by integrating the splitting kernels over different phase-space regions that depend on the hard-scattering observables of interest. The collinear functions depend on an auxiliary vector n μ that can be either light-like (n 2 = 0) or time-like (n 2 > 0). In the case of transverse-momentum dependent (TMD) collinear functions, we show that the use of a time-like auxiliary vector avoids the rapidity divergences, which are instead present if n 2 = 0. The perturbative computation of the collinear functions lead to infrared (IR) divergences that can be properly factorized with respect to IR finite functions that embody the logarithmically-enhanced collinear contributions to hard-scattering cross sections. We evaluate various collinear functions and their n μ dependence at O $$ \mathcal{O} $$ (α S). We compute the azimuthal-correlation component of the TMD collinear functions at O α S 2 $$ \mathcal{O}\left({\alpha}_{\textrm{S}}^2\right) $$ , and we present the results of the O α S 2 $$ \mathcal{O}\left({\alpha}_{\textrm{S}}^2\right) $$ contribution of linearly-polarized gluons to transverse-momentum resummation formulae. Beyond O α S 2 $$ \mathcal{O}\left({\alpha}_{\textrm{S}}^2\right) $$ the collinear functions of initial-state colliding partons are process dependent, as a consequence of the violation of strict collinear factorization of QCD squared amplitudes.
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