Vortex Nucleons as Partial-Wave Filters in Nucleon--Nucleon Scattering

Abstract

We propose vortex nucleon scattering as an angular-momentum-resolved probe of nucleon--nucleon partial waves. Using the standard LSJ partial-wave S matrix as input, we show that an on-axis vortex incident state with a fixed orbital angular-momentum projection mL= imposes the direct selection rule L≥ || on the initial nucleon--nucleon partial waves. As a result, the initial S wave is excluded for =1, while both the initial S and P waves are excluded for =2. The underlying phase shifts are not modified. Instead, the vortex external state changes how the ordinary partial waves are projected into the scattering amplitude. We further analyze off-axis scattering, where the displacement of the target from the vortex axis introduces Bessel-function weights and partially relaxes the on-axis selection rule. These results suggest that vortex nucleons can provide a new experimental handle on the partial-wave content of the strong nucleon--nucleon interaction.