Investigation of the determination of nuclear deformation using high-energy heavy-ion scattering

Abstract

Background: Nuclear deformation provides a crucial characteristic of nuclear structure. Conventionally, the quadrupole deformation length of a nucleus, δ2, has often been determined based on a macroscopic model through a deformed nuclear potential with the deformation length δ (pot)2, which is determined to reproduce the nuclear scattering data. This approach assumes δ2=δ (pot)2 although there is no theoretical foundation. Purpose: We clarify the relationship between δ2 and δ (pot)2 for high-energy heavy-ion scattering systematically to evaluate the validity of the conventional approach to determine the nuclear deformation. Method: The deformation lengths for the 12C inelastic scattering by 12C, 16O, 40Ca, and 208Pb targets at E/A = 50--400 MeV are examined. First, we perform microscopic coupled-channel (CC) calculations to relate δ2 of the deformed density into the inelastic scattering cross section. Second, we use the deformed potential model to determine δ (pot)2 so as to reproduce the microscopic CC result. We then compare δ (pot)2 with δ2. Results: We find that δ (pot)2 is about 20--40 \% smaller than presumed δ2, showing strong energy and target dependence. Further analysis, which considers higher-order deformation effects beyond the derivative model, reveals that δ (pot)2 is still about 15--35 \% smaller than δ2. Conclusion: Our results suggest that one needs to be careful when the deformed potential model for the high-energy heavy-ion scattering is used to extract the nuclear deformation. The conventional approach may underestimate the deformation length δ2 systematically.