Study of p and p scatterings via quasipotential Bethe-Salpeter equation

Abstract

Motivated by recent BESIII measurements of the p p and p p scattering processes, we investigate these reactions within the framework of the quasipotential Bethe-Salpeter equation using an effective Lagrangian approach. The interaction potentials are constructed via a one-boson-exchange model incorporating pseudoscalar, scalar, and vector meson exchanges, along with coupled-channel effects from the N and N channels. For the p p reaction, the total cross sections from threshold up to s = 2.5~GeV are well reproduced. A mild enhancement near the N threshold is attributed to coupled-channel dynamics. Using parameters constrained by the total cross section data, our model also predicts differential cross sections at s = 2.24~GeV, which exhibit weak angular dependence, consistent with experimental observations. Partial-wave analysis indicates that the 1+ partial wave dominates over the entire energy range, while the 0+ wave plays a significant role near threshold. For the p p reaction, our predicted total cross sections show good agreement with the BESIII data. The 1- partial wave is found to dominate in most of the energy region. Notably, the calculated differential cross sections exhibit a strong forward peaking behavior, consistent with experimental findings and understood as resulting from constructive interference among various partial waves. This forward-peaked angular distribution persists across a range of energies, highlighting the distinct dynamics of the p interaction.