An analytic solution to LO coupled DGLAP evolution equations: a new pQCD tool

Abstract

We have analytically solved the LO pQCD singlet DGLAP equations using Laplace transform techniques. Newly-developed highly accurate numerical inverse Laplace transform algorithms allow us to write fully decoupled solutions for the singlet structure function Fs(x,Q2)and G(x,Q2) as Fs(x,Q2)= Fs(Fs0(x), G0(x)) and G(x,Q2)= G(Fs0(x), G0(x)). Here Fs and G are known functions of the initial boundary conditions Fs0(x) = Fs(x,Q02) and G0(x) = G(x,Q02), i.e., the chosen starting functions at the virtuality Q02. For both G and Fs, we are able to either devolve or evolve each separately and rapidly, with very high numerical accuracy, a computational fractional precision of O(10-9). Armed with this powerful new tool in the pQCD arsenal, we compare our numerical results from the above equations with the published MSTW2008 and CTEQ6L LO gluon and singlet Fs distributions, starting from their initial values at Q02=1 GeV2 and 1.69 GeV2, respectively, using their choices of αs(Q2). This allows an important independent check on the accuracies of their evolution codes and therefore the computational accuracies of their published parton distributions. Our method completely decouples the two LO distributions, at the same time guaranteeing that both G and Fs satisfy the singlet coupled DGLAP equations. It also allows one to easily obtain the effects of the starting functions on the evolved gluon and singlet structure functions, as functions of both Q2 and Q02, being equally accurate in devolution as in evolution. Further, it can also be used for non-singlet distributions, thus giving LO analytic solutions for individual quark and gluon distributions at a given x and Q2, rather than the numerical solutions of the coupled integral-differential equations on a large, but fixed, two-dimensional grid that are currently available.