Nucleon-pion-state contamination in lattice calculations of the axial form factors of the nucleon

Abstract

The nucleon-pion-state contribution to QCD two- and three-point functions used in the calculation of the axial form factors of the nucleon are studied in chiral perturbation theory. For physically small quark masses the nucleon-pion states are expected to dominante the excited-state contamination at large euclidean time separations. To leading order in chiral perturbation theory the results depend on two experimentally well-known low-energy constants only and the nucleon-pion-state contribution can be reliably estimated. The nucleon-pion-state contribution to the axial form factor G A(Q2) is at the 5 percent level for source-sink separations of 2 fm and shows almost no dependence on the momentum transfer Q2. In contrast, for the induced pseudo scalar form factor G P(Q2) the nucleon-pion-state contribution shows a rather strong dependence on Q2 and leads to a 10 to 40 percent underestimation of G P(Q2) at small momentum transfers. Applying the ChPT results to recent lattice data generated by the PACS collaboration we find agreement with experimental data and the predictions of the pion-pole dominance model.