Hadronic light-by-light scattering in the muon g-2: impact of proposed measurements of the (pi0 -> gamma gamma) decay width and the (gamma* gamma -> pi0) transition form factor with the KLOE-2 experiment

Abstract

The calculation of the hadronic light-by-light scattering contribution to the muon g-2 currently relies entirely on models. Measurements of the form factors which describe the interactions of hadrons with photons can help to constrain the models and reduce the uncertainty in amu(had. LbyL) = (116 40) x 10-11. In the dominant pion-exchange contribution, the form factor Fpi0*gamma*gamma*((q1 + q2)2, q12, q22) with an off-shell pion enters. In general, measurements of the transition form factor F(Q2) = Fpi0*gamma*gamma*(mpi2, -Q2, 0) are only sensitive to a subset of the model parameters. Thus, having a good description for F(Q2) is only necessary, not sufficient, to determine amu(LbyL; pi0). Simulations have shown that measurements at KLOE-2 should be able to determine the (pi0 -> gamma gamma) decay width to 1% statistical precision and the transition form factor for small space-like momenta, 0.01 GeV2 < Q2 < 0.1 GeV2, to 6% precision. In the two-loop integral for the pion-exchange contribution the relevant regions of momenta are in the range 0 - 1.5 GeV. With the (pi0 -> gamma gamma) decay width from the PDG [PrimEx] and current data for the transition form factor, the error on amu(LbyL; pi0) is ( 4 x 10-11) [ 2 x 10-11], not taking into account the uncertainty related to the off-shellness of the pion. Including the simulated KLOE-2 data reduces the error to ( (0.7 - 1.1) x 10-11). For models like VMD, which have only few parameters that are completely determined by measurements of F(Q2), this represents the total error. But maybe such models are too simplistic. In other models, e.g. those based on large-Nc QCD, parameters describing the off-shell pion dominate the uncertainty in amu; large-Nc(LbyL; pi0) = (72 12) x 10-11.