The new measured data of elastic and inelastic 20Ne+130Te scattering at an energy of 15.3 A MeV are analyzed in framework of the nuclear optical potential.Three types of semi-microscopic potentials are used:the real p...The new measured data of elastic and inelastic 20Ne+130Te scattering at an energy of 15.3 A MeV are analyzed in framework of the nuclear optical potential.Three types of semi-microscopic potentials are used:the real part is calculated using a double folding model in conjunction with the conventional phenomenological Woods-Saxon(WS)potential for the imaginary part.Two real cluster models are constructed using the cluster structure of^(20)Ne nucleus as 5αandα+^(16)O.The real part of the third potential is generated using a CDM3Y6 interaction employed for comparison.Three excited energies to the superposition of the projectile and target states,ground-state(Quasi),1.6 and 2.5 MeV are investigated using deformed potentials.The contributions of these states are calculated using a one-step distorted wave Born approximation and coupled Channels approaches.Successful calculations and results using semi-microscopic potentials in simple one-channel and coupled channels are obtained.The values of cross section and volume integrals require more contributions to enable more comparisons regarding this project.展开更多
文摘The new measured data of elastic and inelastic 20Ne+130Te scattering at an energy of 15.3 A MeV are analyzed in framework of the nuclear optical potential.Three types of semi-microscopic potentials are used:the real part is calculated using a double folding model in conjunction with the conventional phenomenological Woods-Saxon(WS)potential for the imaginary part.Two real cluster models are constructed using the cluster structure of^(20)Ne nucleus as 5αandα+^(16)O.The real part of the third potential is generated using a CDM3Y6 interaction employed for comparison.Three excited energies to the superposition of the projectile and target states,ground-state(Quasi),1.6 and 2.5 MeV are investigated using deformed potentials.The contributions of these states are calculated using a one-step distorted wave Born approximation and coupled Channels approaches.Successful calculations and results using semi-microscopic potentials in simple one-channel and coupled channels are obtained.The values of cross section and volume integrals require more contributions to enable more comparisons regarding this project.
