An imaginary potential with universal normalization for dissipative processes in heavy-ion reactions

“…The JLM interaction is a very simple complex effective N N interaction and easy to handle in the folding calculations and, hence, has widely been used in the nucleon-nucleus systems. Another widely-used interaction model is the São Paulo potential (SPP) [24][25][26] that is the DFM potential multiplied by the local-velocity-dependent Pauli non-locality correction factor. Both models still suffer from uncertainty originating from either existence of the free parameters or the lack of theoretical foundation of the models and assumptions.…”

Channel coupling effect and important role of imaginary part of coupling potential for high-energy heavy-ion scatterings

“…The JLM interaction is a very simple complex effective N N interaction and easy to handle in the folding calculations and, hence, has widely been used in the nucleon-nucleus systems. Another widely-used interaction model is the São Paulo potential (SPP) [24][25][26] that is the DFM potential multiplied by the local-velocity-dependent Pauli non-locality correction factor. Both models still suffer from uncertainty originating from either existence of the free parameters or the lack of theoretical foundation of the models and assumptions.…”

Channel coupling effect and important role of imaginary part of coupling potential for high-energy heavy-ion scatterings

“…This is discussed in detail in [5]. The resulting nuclear potential is presented in the following equation:…”

“…With this potential a varied number of systems can be described very well (in CC calculations), such as: p+ 40 Ca, n+ 27 Al, 16 O+ 27 Al, 16 O+ 60 Ni, 58 Ni+ 124 Sn [5], without the readjustment of any parameter. For weakly bound cases, however, a modification of the real potential is necessary.…”

“…It does not contain any adjustable parameter and, combined with coupled channel (CC) calculations, provides a powerful tool for predicting cross sections for quite different systems and energies around the Coulomb barrier [4]. Recently, a new generation of SPP/CC calculations has been developed [5] with the aim of describing reactions at energies for which dissipative processes, such as deep inelastic collisions (DIC), are important. This has been done with the introduction of an imaginary potential with the same shape of the SPP, and the predictions have been confirmed in diverse systems.…”

Exploring the potential of the São Paulo Potential

“…The experiment was performed at the INFN-LNS laboratory in Catania using the large acceptance magnetic spectrometer MAGNEX [2][3][4]. The data analysis, based on parameter-free Coupled Channel (CC) calculations [5] and the São Paulo double folding potential, (SPP) [6] has confirmed the formation of a nuclear rainbow [7]. The failure of Optical Model (OM) calculations with the same optical potential in reproducing the measured cross sections reveals the crucial role of inelastic couplings in the rainbow formation.…”

Effects of configuration mixing in heavy-ion elastic scattering