Interaction potentials for two-particle states with non-zero total momenta in lattice QCD

Abstract

In this study, we extend the HAL QCD method to a case where a total momentum of a two-particle system is non-zero and apply it to the I=2 S-wave ππ scattering in order to confirm its validity. We derive a fundamental relation of an energy-independent non-local potential defined in the center of mass frame with NBS wave functions in a laboratory frame. Based on the relation, we propose the time-dependent method to extract potentials, often used in practice for the HALQCD method in the center of mass frame. For numerical simulations in the I=2 ππ system, we employ (2+1)-flavor gauge configurations on a 323 × 64 lattice at the lattice spacing a ≈ 0.0907 fm and mπ ≈ 700 MeV. Both effective leading order (LO) potentials and corresponding phase shifts obtained in laboratory frames agree with those obtained in the center-of-mass frame by the conventional HAL QCD method within somewhat larger statistical errors. In addition, we observe a consistency in scattering phase shifts between ours and results by the finite-volume method as well. The HAL QCD method with non-zero total momenta, established in this study, brings more flexibility to the HAL QCD method, which enables us to handle systems having the same quantum numbers with a vacuum or to access energy regions prohibited in the center of mass frame.