Decoupling the coupled DGLAP evolution equations: an analytic solution to pQCD
Abstract
Using Laplace transform techniques, along with newly-developed accurate numerical inverse Laplace transform algorithms, we decouple the solutions for the singlet structure function and of the two leading-order coupled singlet DGLAP equations, allowing us to write fully decoupled solutions: F_s(x,Q^2)={\cal F}_s(F_{s0}(x), G_0(x)), G(x,Q^2)={\cal G}(F_{s0}(x), G_0(x)). Here and are known functions---found using the DGLAP splitting functions---of the functions and , the chosen starting functions at the virtuality . As a proof of method, we compare our numerical results from the above equations with the published MSTW LO gluon and singlet distributions, starting from their initial values at . Our method completely decouples the two LO distributions, at the same time guaranteeing that both distributions satisfy the singlet coupled DGLAP equations. It furnishes us with a new tool for readily obtaining the effects of the starting functions (independently) on the gluon and singlet structure functions, as functions of both and . In addition, it can also be used for non-singlet distributions, thus allowing one to solve analytically for individual quark and gluon distributions values at a given and , with typical numerical accuracies of about 1 part in , rather than having to evolve numerically coupled integral-differential equations on a two-dimensional grid in , as is currently done.
Keywords
Cite
@article{arxiv.1004.1440,
title = {Decoupling the coupled DGLAP evolution equations: an analytic solution to pQCD},
author = {Martin M. Block and Loyal Durand and Phuoc Ha and Douglas W. McKay},
journal= {arXiv preprint arXiv:1004.1440},
year = {2010}
}
Comments
6 pages, 2 figures