The Nuclear Matter Test of Variational Effective Interactions (Published)

This paper presents the nuclear matter test of seven variational effective interactions derived on the basis of lowest order constrained variational approach (LOCV). Three of these effective interactions, derived from the matrix elements of the Reid93 potential and named N3Y-Fetal, N’3Y-Fetal and N^∗3Y-Fetal based on nuclear systems A = 16, 40 and 90 respectively, are primarily studied and compared with the first set of four effective interactions, derived from the matrix elements of the Reid68, consisting of the B3Y-Fetal, B^′3Y-Fetal, B^∗3Y-Fetal and B^†3Y-Fetal effective interactions based on nuclear systems A = 16, 24, 40 and 90 respectively. The results of this study have revealed that the binding energies E_A0 = -8.6, -12.3 and -7.7 MeV of the cold symmetric nuclear matter (SNM) respectively produced by N3Y-Fetal, N^′3Y-Fetal and N^∗3Y-Fetal effective interactions at the saturation density, ρ₀ = 0.17fm⁻³ clearly reflect their mass dependence, but do not satisfy the saturation condition, E_A0= -16.0±1 MeV, meaning they have failed to reproduce the saturation properties of nuclear matter. Comparing these effective interactions with the B3Y-Fetal, B^′3Y-Fetal, B^∗3Y-Fetal and B^†3Y-Fetal effective interactions with the binding energies, E_A0 = -15.2, -14.5, -11.2 and -8.2 MeV respectively for SNM at the saturation density, the findings of this study have established the B3Y-Fetal, out of the seven variational effective interactions presented herein, as the most viable with the highest predictive power, followed by the B’3Y-Fetal effective interaction. Following this, a review of the performance of the B3Y-Fetal effective interaction in nuclear matter and nuclear reactions in its DDM3Yn, BDM3Yn and CDM3Yn density dependences, leading to the presentation of the new B3Y-Fetal-based CDM3Y-K parametrizations and the DDB3Y1-Fetal and BDB3Y1-Fetal curves of equation of state in this work, has so far shown it to be in excellent agreement with the M3Y-Reid and M3Y-Paris effective interactions. These findings indicate the possibility of its successful application in α-nucleus elastic scattering, nuclear fusion, α- and cluster-radioactive decay in future research efforts

Keywords: Interactions, matter, nuclear, test of variational

A Study of Asymmetric Nuclear Matter with the B3Y-Fetal Effective Interaction (Published)

In this paper, the asymmetric nuclear matter is studied within the framework of Hartree-Fock approximation with the B3Y-Fetal interaction, a new M3Y-type ef­fective nucleon-nucleon interaction based on the lowest order constrained varia­tional approach (LOCV). This study has been carried out to ascertain and validate the viability of the new effective interaction. For comparative purposes, the fa­mous M3Y-Paris and M3Y-Reid effective interactions are used in this study. The B3Y-Fetal has been used in our previous work in its various density-dependent versions to successfully reproduce the saturation properties of the cold symmetric nuclear matter at the saturation density, ρ = 0.17fm^-3. It has been used herein in its DDM3Y1, BDM3Y0 and BDM3Y1 density dependent versions to compute the binding energy per nucleon, also called equation of state (EOS), incompressibility and pressure of asymmetric nuclear matter with results that have proven to be ac­ceptably in agreement with previous work done with the M3Y-Paris and M3Y-Reid by other researchers.

Keywords: B3Y-Fetal, asymmetric nuclear, effective interaction, matter