Perturbative stability of the QCD predictions for the ratio R=FL/FT and azimuthal asymmetry in heavy-quark leptoproduction

Abstract

We analyze the perturbative and parametric stability of the QCD predictions for the Callan-Gross ratio R(x,Q2)=FL/FT and azimuthal (2) asymmetry in heavy-quark leptoproduction. Our analysis shows that large radiative corrections to the structure functions cancel each other in their ratio R(x,Q2) and azimuthal asymmetry with good accuracy. As a result, the NLO contributions to the Callan-Gross ratio and (2) asymmetry are less than 10% in a wide region of the variables x and Q2. We provide compact analytic predictions for R(x,Q2) and asymmetry in the case of low x 1. Simple formulae connecting the high-energy behavior of the Callan-Gross ratio and azimuthal asymmetry with the low-x asymptotics of the gluon density in the target are derived. It is shown that the obtained hadron-level predictions for R(x,Q2) and azimuthal asymmetry are stable at x 1 under the DGLAP evolution of the gluon distribution function. Concerning the experimental aspects, we propose to exploit the observed perturbative stability of the Callan-Gross ratio and (2) asymmetry in the extraction of the structure functions from the corresponding reduced cross sections. In particular, our obtained analytic expressions simplify essentially the determination of F2c(x,Q2) and F2b(x,Q2) from available data of the H1 Collaboration. Our results will also be useful in extraction of the azimuthal asymmetries from the incoming and future data on heavy-quark leptoproduction.