Pion elastic and (π0,η,η')γγ* transition form factors in a broad range of momentum transfers

Abstract

We analyze Fπ(Q2) and FPγ(Q2), P=π,η,η', within the local-duality (LD) version of QCD sum rules, which allows one to obtain predictions for hadron form factors in a broad range of momentum transfers. To probe the accuracy of this approximate method, we consider, in parallel to QCD, a potential model: in this case, the exact form factors may be calculated from the solutions of the Schr\"odinger equation and confronted with the results from the quantum-mechanical LD sum rule. On the basis of our quantum-mechanical analysis we conclude that the LD sum rule is expected to give reliable predictions for Fπ(Q2) and Fπγ(Q2) in the region Q2 5-6 GeV2. Moreover, the accuracy of the method improves rather fast with growing Q2 in this region. For the pion elastic form factor, the data at small Q2 indicate that the LD limit may be reached already at relatively low values of momentum transfers, Q2≈ 4-8 GeV2; we therefore conclude that large deviations from LD in the region Q2=20-50 GeV2 reported in some recent theoretical analyses seem unlikely. The data on the (η,η')γγ* form factors meet very well the expectations from the LD model. Surprisingly, the BaBar results for the π0γγ* form factor imply a violation of LD growing with Q2 even at Q2≈ 40 GeV2, at odds with the η,η' case and the experience from quantum mechanics.