Charge-changing-cross-section measurements of 12-16C at around 45A MeV and development of a Glauber model for incident energies 10A-2100A MeV

Abstract

We have measured for the first time the charge-changing cross sections (σCC) of 12-16C on a 12C target at energies below 100A MeV. To analyze these low-energy data, we have developed a finite-range Glauber model with a global parameter set within the optical-limit approximation which is applicable to reaction cross section (σR) and σCC measurements at incident energies from 10A to 2100A MeV. Adopting the proton-density distribution of 12C known from the electron-scattering data, as well as the bare total nucleon-nucleon cross sections, and the real-to-imaginary-part ratios of the forward proton-proton elastic scattering amplitude available in the literatures, we determine the energy-dependent slope parameter β pn of the proton-neutron elastic differential cross section so as to reproduce the existing σR and interaction-cross-section data for 12C+12C over a wide range of incident energies. The Glauber model thus formulated is applied to calculate the σ R's of 12C on a 9Be and 27Al targets at various incident energies. Our calculations show excellent agreement with the experimental data. Applying our model to the σ R and σ CC for the "neutron-skin" 16C nucleus, we reconfirm the importance of measurements at incident energies below 100A MeV. The proton root-mean-square radii of 12-16C are extracted using the measured σCC's and the existing σR data. The results for 12-14C are consistent with the values from the electron scatterings, demonstrating the feasibility, usefulness of the σCC measurement and the present Glauber model.