Collinear functions for QCD resummations
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 that can be either light-like or time-like . 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 . 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 dependence at . We compute the azimuthal-correlation component of the TMD collinear functions at , and we present the results of the contribution of linearly-polarized gluons to transverse-momentum resummation formulae. Beyond 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.
Keywords
Cite
@article{arxiv.2208.05840,
title = {Collinear functions for QCD resummations},
author = {Stefano Catani and Prasanna K. Dhani},
journal= {arXiv preprint arXiv:2208.05840},
year = {2023}
}
Comments
55 pages; some comments added, results unchanged