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 Fs(x,Q2) and G(x,Q2) of the two leading-order coupled singlet DGLAP equations, allowing us to write fully decoupled solutions: Fs(x,Q2)= Fs(Fs0(x), G0(x)), G(x,Q2)= G(Fs0(x), G0(x)). Here Fs and G are known functions---found using the DGLAP splitting functions---of the functions Fs0(x) Fs(x,Q02) and G0(x) G(x,Q02), the chosen starting functions at the virtuality Q02. As a proof of method, we compare our numerical results from the above equations with the published MSTW LO gluon and singlet Fs distributions, starting from their initial values at Q02=1 GeV2. 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 Q2 and Q02. 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 x and Q2, with typical numerical accuracies of about 1 part in 105, rather than having to evolve numerically coupled integral-differential equations on a two-dimensional grid in x, Q2, as is currently done.