Generalized parton distributions from the off-forward Compton amplitude in lattice QCD

We determine the properties of generalized parton distributions (GPDs) from a lattice QCD calculation of the off-forward Compton amplitude (OFCA). By extending the Feynman-Hellmann relation to second-order matrix elements at off-forward kinematics, this amplitude can be calculated from lattice propagators computed in the presence of a background field. Using an operator product expansion, we show that the deeply virtual part of the OFCA can be parametrized in terms of the low-order Mellin moments of the GPDs. We apply this formalism to a numerical investigation for zero-skewness kinematics at two values of the soft momentum transfer, t = -1.1, -2.2 GeV2, and a pion mass of m(pi) approximate to 470 MeV. The form factors of the lowest two moments of the nucleon GPDs are determined, including the first lattice QCD determination of the n = 4 moments. Hence we demonstrate the viability of this method to calculate the OFCA from first principles, and thereby provide novel constraint on the x- and t-dependence of GPDs.

Automated summary

In this study, the properties of generalized parton distributions (GPDs) are determined from a lattice QCD calculation of the off-forward Compton amplitude (OFCA). By extending the Feynman-Hellmann relation to second-order matrix elements at off-forward kinematics, the OFCA can be calculated from lattice propagators computed in the presence of a background field. Using an operator product expansion, the deeply virtual part of the OFCA is parametrized in terms of the low-order Mellin moments of the GPDs. Numerical investigations are conducted to determine the form factors of the lowest two moments of the nucleon GPDs at zero-skewness kinematics. This study provides novel constraints on the x- and t-dependence of GPDs and demonstrates the viability of calculating the OFCA from first principles.