dc.description.abstract |
Nuclear shell-model is a theoretical framework which has been extensively used for understanding
the nuclear structure properties. Its success mainly depends on the choice
of effective interaction. In recent years, however, attention has been shifted towards the
individual components of the effective interaction, namely the central, spin-orbit, and tensor
forces, due to their role in understanding shell evolution and shell gaps. Except for
the spin-orbit force, the central and tensor force components possess systematic properties
in shell-model effective interactions. Particularly, the tensor force monopole matrix elements
originating from the bare tensor force are observed to retain systematic properties in
shell-model effective interactions, and hardly change against the various renormalization
procedures. However, in our observation, we found that some widely used shell-model
effective interactions do not share these systematic properties. The deviations in the systematic
properties may originate from the imprecise normalization of the contribution of
higher-order in-medium terms and many-body force, particularly the three-body, to their
initial two-body matrix elements, and/or the empirical modification based on the experimental
observables.
The objective of this thesis is to determine the deviations in the known systematics of
the individual force components of effective interaction, and try to incorporate the missing
features back into the original interaction. In our study, the spin-tensor decomposition
method was used to investigate the known systematic features of the central, spin-orbit,
and tensor force components of the effective interaction. The calculations in our study
were carried out using a large-scale shell model framework.
In our study, we found that seven out of ten T = 1 tensor force monopole matrix elements
of widely used GX-interactions of pf -shell do not share the systematic properties as
reported. We ameliorate this disparity by making use of Yukawa-type tensor force. The revised
interaction has been tested from Ca to Ge isotopes with various physics viewpoints.
The results are found to be satisfactory with respect to the experimental data. We have
attempted and succeeded in incorporating the systematic properties of tensor forces to a
good extent. Despite the changes to the interaction on a very large scale, we still obtained
reasonable results as compared to the experimental data.
Further, we have extended our theoretical investigations for p-shell. For p-shell effective
interaction CK(8-16), we found that Isospin T = 0 tensor force monopole matrix
elements do not share these systematic. We correct the discrepancies present in CK(8-16)
interaction, and the revised interaction CKN has been tested for the calculations of excitation
spectra, electromagnetic moments, and electromagnetic and Gamow-Teller (GT)
transitions of p-shell nuclei of normal parity states. The results achieved using interaction
CKN agree well with the experimental data and are found to improve the previously
predicted theoretical results. Furthermore, our use of the analytical expression of the tensor force to improve the
disparities in p and pf -shell effective interactions motivates us to apply it to higher shells,
where conventional studies based on spin tensor decomposition are not feasible due to
the mathematical restrictions. We have used this approach to study the significance of
tensor force in the p f5g9-region, particular focus on the most visible monopole migration
of p1p3=2 and p0 f5=2 orbitals when n0g9=2 orbital is filled with neutrons. The results
obtained in our study from various physics viewpoints are consistent with what is stated in
the literature. |
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