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ACCURACY OF THE MULTIPOLE EXPANSION OF DENSITY DISTRIBUTION IN THE PRESENCE OF OCTUPOLE DEFORMATION

M. ISMAIL

Department of Physics, Faculity of Science, Cairo University, Giza, Egypt

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M. M. BOTROS

Department of Physics, Faculity of Science, Cairo University, Giza, Egypt

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, and

A. A. WHEIDA

Department of Physics, National Research Center, Giza, Egypt

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https://doi.org/10.1142/S0218301311020423Cited by:0 (Source: Crossref)

Abstract

The accuracy of multipole expansion of density distribution for deformed nuclei is tested. The interaction potential for a deformed-spherical pair of nuclei was calculated using the folding model derived from zero-range nucleon–nucleon (NN) interaction. We considered two spherical projectiles Ca⁴⁰ and Pb²⁰⁸ scattered on U²³⁸ deformed target nucleus. The error in the heavy ion (HI) potential resulting from using a truncated multipole density expansion is evaluated for each case in the presence of octupole deformation δ₃ besides quadrupole δ₂. We are interested in the value of error for R ≥ R_T (touching distance). We found that for values of |δ₃|≤0.1 the error at R = R_T reaches reasonable values when six terms expansion is used. For |δ₃| = 0.2, we calculated the Coulomb barrier parameters using realistic NN force and found that the large error present in six terms for zero range force decreases strongly to less than 1% when the zero range is added to finite range forces and Coulomb interaction to form the Coulomb barrier. It is noted that the negative value of octupole deformation parameters δ₃ = -0.1 produce error at orientation angle θ equal in value to that produced at angle (180°-θ) for the positive values δ₃ = 0.1. We also found that the error decreases as the mass number of the projectile nucleus increases.

Keywords:

Multipole expansion

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