Effective interaction forN=50 isotones

1 March 1988

journal article
research article
Published by American Physical Society (APS) in Physical Review C

Vol. 37 (3) , 1256-1266
https://doi.org/10.1103/physrevc.37.1256

Abstract

Standard shell-model techniques of constructing and diagonalizing Hamiltonians in finite Hilbert spaces have been used to treat the N=50 isotones with an expanded model space and a new empirical effective interaction. A vector space with active 0

f_{5 / 2}

, 1

p_{3 / 2}

, 1

p_{1 / 2}

, and 0

g_{9 / 2}

proton orbits is used to model the low-lying excitations of these nuclei. The effective interaction is obtained by varying 35 parameters, distributed over the 65 two-body matrix elements and four single particle energies of the model space, to fit over 170 experimental energy levels in nuclei from

{}^{82}{Ge}

through

{}^{96}{Pd}

. Nearly all of the experimental level energies of N=50 nuclei involved in the fit are well reproduced by the final interaction.

Keywords

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