Your search keyword '"Shell model calculations"' showing total 3 results

1. Proof for strong ascendancy of short range effects on inelastic form factors in some open fp-shell nuclei.

Author

Fadhil, Sanna N., Abdalsattar, Sarrah I., and Al-Rahmani, Altaf A.

Subjects

*VALENCE fluctuations, *MOMENTUM transfer, *DENSITY matrices, *CLUSTERING of particles, *SPACE charge, *NUCLEON-nucleon interactions

Abstract

Short range effects on inelastic C2 form factors in some open fp nuclei ( 4 6 − 5 0 Ti, 5 0 − 5 4 Cr, 5 4 − 5 6 Fe and 6 4 − 6 8 Zn) have been researched. The charge densities in these isotopes have been also researched by the one and two particle components of cluster series using single-particle wavefunctions of the harmonic oscillator potential. The short range effects have been inserted into the two particle components of cluster series employing the Jastrow form correlation. The total form factors of isotopes under consideration arise from the model space and core-polarization participations. The one-body density matrix elements (which are needed for computing the model space transition charge density) of valence nucleons for the transition 0 + → 2 + have been computed by accomplishment of shell model calculations using the OXBASH code with various interactions. The shape of Tassie model has been adopted for computing the core-polarization transition charge density. The present computations are reliant on b (oscillator parameter) and β (correlation parameter), where these parameters have been created independently for each individual nucleus by fitting the computed elastic form factors to those of experimental ones. This study provides a proof for strong ascendancy of short range effects on the present calculations, where inclusion of short range correlations on computations seems to be required for performing a notable modification in the computed outcomes which sequentially causes to elucidate the experimental data astoundingly in the momentum transfer under consideration. [ABSTRACT FROM AUTHOR]

Published

2022

2. New levels in spherical 96Y.

Author

Wang, E. H., Hamilton, J. H., Ramayya, A. V., Han, R., Zachary, C. J., Eldridge, J. M., Hwang, J. K., Brewer, N. T., Luo, Y. X., Rasmussen, J. O., Zhu, S. J., Ter-Akopian, G. M., and Oganessian, Yu. Ts.

Subjects

*SPHERICAL astronomy, *NEUTRONS, *NUCLEAR reactors, *DEFORMATIONS (Mechanics), *PHYSICS experiments, *NILSSON model

Abstract

New transitions in neutron rich 96Y have been identified by analyzing the high statistics γ-γ-γ and γ-γ-γ-γ coincidence data from the spontaneous fission of 252Cf at the Gammasphere detector array. Shell model calculations were performed and are found in good agreement with experimental data. The ground state is nearly spherical but a new excited band has large deformation. [ABSTRACT FROM AUTHOR]

Published

2018

3. SHELL MODEL DESCRIPTION OF 102-108Sn ISOTOPES.

Author

TRIVEDI, T., SRIVASTAVA, P. C., NEGI, D., and MEHROTRA, I.

Subjects

*NUCLEAR shell theory, *TIN isotopes, *NEUTRONS, *PARTICLES (Nuclear physics), *NUCLEAR models, *NUCLEAR energy

Abstract

We have performed shell model calculations for neutron deficient even 102-108Sn and odd 103-107Sn isotopes in sdg7/2h11/2 model space using two different interactions. The first set of interaction is due to Brown et al. and second is due to Hoska et al. The calculations have been performed using doubly magic 100Sn as core and valence neutrons are distributed over the single particle orbits 1g7/2, 2d5/2, 2d3/2, 3s1/2 and 1h11/2. In more recent experimental work for 101Sn [I. G. Darby et al., Phys. Rev. Lett.105 (2010) 162502], the g.s. is predicted as 5/2+ with excited 7/2+ at 172 keV. We have also performed another two set of calculations by taking difference in single particle energies of 2d5/2 and 1g7/2 orbitals by 172 keV. The present state-of-the-art shell model calculations predict fair agreement with the experimental data. These calculations serve as a test of nuclear shell model in the region far from stability for unstable Sn isotopes near the doubly magic 100Sn core. [ABSTRACT FROM AUTHOR]

Published

2012