On non-singlet physical evolution kernels and large-x coefficient functions in perturbative QCD
Abstract
We study the large-x behaviour of the physical evolution kernels for flavour non-singlet observables in deep-inelastic scattering, where x is the Bjorken variable, semi-inclusive e^+ e^- annihilation and Drell-Yan lepton-pair production. Unlike the corresponding MSbar-scheme coefficient functions, all these kernels show a single-logarithmic large-x enhancement at all orders in 1-x. We conjecture that this universal behaviour, established by Feynman-diagram calculations up to the fourth order, holds at all orders in the strong coupling constant alpha_s. The resulting predictions are presented for the highest ln^n(1-x) contributions to the higher-order coefficient functions. In Mellin-N space these predictions take the form of an exponentiation which, however, appears to be less powerful than the well-known soft-gluon exponentiation of the leading (1-x)^(-1) ln^n(1-x) terms. In particular in deep-inelastic scattering the 1/N corrections are non-negligible for all practically relevant N.
Cite
@article{arxiv.0909.2124,
title = {On non-singlet physical evolution kernels and large-x coefficient functions in perturbative QCD},
author = {S. Moch and A. Vogt},
journal= {arXiv preprint arXiv:0909.2124},
year = {2009}
}
Comments
33 pages, LaTeX, 4 eps-figures