Unified optical-model approach to low-energy antiproton annihilation on nuclei and to antiprotonic atoms
Abstract
A successful unified description of p nuclear interactions near E=0 is achieved using a p optical potential within a folding model, V opt v * , where a p p potential v is folded with the nuclear density . The potential v fits very well the measured p p annihilation cross sections at low energies (pL < 200 MeV/c) and the 1s and 2p spin-averaged level shifts and widths for the pH atom. The density-folded optical potential V opt reproduces satisfactorily the strong-interaction level shifts and widths over the entire periodic table, for A > 10, as well as the few low energy p annihilation cross sections measured on Ne. Both v and V opt are found to be highly absorptive, which leads to a saturation of reaction cross sections in hydrogen and on nuclei. Predictions are made for p annihilation cross sections over the entire periodic table at these very low energies and the systematics of the calculated cross sections as function of A, Z and E is discussed and explained in terms of a Coulomb-modified strong-absorption model. Finally, optical potentials which fit simultaneously low-energy p - 4He observables for E < 0 as well as for E > 0 are used to assess the reliability of extracting Coulomb modified p nuclear scattering lengths directly from the data. The relationship between different kinds of scattering lengths is discussed and previously published systematics of the p nuclear scattering lengths is updated.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.