Investigation of the Nuclear Structure of Some Ni and Zn Isotopes with Skyrme-Hartree-Fock Interaction

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Published: Aug 1, 2022
DOI: https://doi.org/10.21123/bsj.2022.19.4.0914
Keywords:
Charge density distribution (CDD), C2 form factors, Skyrme-Hartree-Fock, Shell model

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Shaimaa A Abbas
Department of Physics, College of Education for Pure Science (Ibn-Alhaitham), University of Baghdad, Baghdad, Iraq.
https://orcid.org/0000-0002-5580-233X
Seham Hassan Salman
Department of Physics, College of Education for Pure Science (Ibn-Alhaitham), University of Baghdad, Baghdad, Iraq.
Samira A. Ebrahiem
Department of Physics, College of Education for Pure Science (Ibn-Alhaitham), University of Baghdad, Baghdad, Iraq.
Huda M. Tawfeek
Department of Physics, College of Education for Pure Science (Ibn-Alhaitham), University of Baghdad, Baghdad, Iraq.
https://orcid.org/0000-0003-1602-8545

Abstract

The inelastic C2 form factors and the charge density distribution (CDD) for 58,60,62Ni and 64,66,68Zn nuclei has been investigated by employing the Skyrme-Hartree-Fock method with (Sk35-Skzs*) parametrization. The inelastic C2 form factor is calculated by using the shape of Tassie and Bohr-Mottelson models with appropriate proton and neutron effective charges to account for the core-polarization effects contribution. The comparison of the predicted theoretical values was conducted with the available measured data for C2 and CDD form factors and showed very good agreement.

Received 19/6/2021

Accepted 31/8/2021

Published Online First 20/1/2022

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Investigation of the Nuclear Structure of Some Ni and Zn Isotopes with Skyrme-Hartree-Fock Interaction. Baghdad Sci.J [Internet]. 2022 Aug. 1 [cited 2025 Jan. 19];19(4):0914. Available from: https://bsj.uobaghdad.edu.iq/index.php/BSJ/article/view/6426
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Vol. 19 No. 4 (2022): Issue 4
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1.
Investigation of the Nuclear Structure of Some Ni and Zn Isotopes with Skyrme-Hartree-Fock Interaction. Baghdad Sci.J [Internet]. 2022 Aug. 1 [cited 2025 Jan. 19];19(4):0914. Available from: https://bsj.uobaghdad.edu.iq/index.php/BSJ/article/view/6426
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References

de Forest T, Walecka JD. Electron scattering and nuclear structure. Adv.Phys.1966 Jun;15:1-109.

Liu J, Zhang X, Xu C, Ren Z. Theoretical study on nuclear structure by the multiple Coulomb scattering and magnetic scattering of relativistic electrons. Nucl.Phys A 2016. Apr; 948: 46-16.

Karataglidis S. Mapping the densities of exotic nuclei. PoS Proc. Sci.2016.Sep; INPC2016. The 26th International Nuclear Physics Conference 11-16 September, 2016, Adelaide, Australia.

Hamada T, Johnston, ID. A potential model representation of two-nucleon data below 315 MeV. Nucl. Phys. 1962 Jun; 34:382-21.

Kuo TTS, Brown GE. Reaction matrix elements for the 0f-1p shell nuclei. Nucl. Phys. A 1968 Jun; 114: 241-38.

Radhi RA, Shell model calculations of inelastic electron scattering for positive and negative parity states in 19F. Nucl. Phys. A 2016 Mar; 947:12-15.

Radhi RA, Alzubadi A A, Ali A H. Magnetic dipole moments, electric quadrupole moments, and electron scattering form factors of neutron-rich sd-pf cross-shell nuclei. Phys. Rev. C 2018 Jun; 97: 064312-13.

Radhi RA, Alzubadi A A. Study the Nuclear Form Factors of Low-Lying Excited States in 7Li Nucleus Using the Shell Model with Skyrme Effective Interaction. Few-Body Syst. 2019 Aug; 60:57-13.

Radhi RA. Calculation of quadrupole transition rates in cross sd-pf shell isotopes (Si, S and Ar). 2nd International Conference on Atomic and Nuclear Physics, November 08-09, 2017 Las Vegas, USA.

Majeed FA. The effect of core polarization on longitudinal form factors in 10B. Phys. Scr. 2012 May; 85:065201-4.

Majeed FA, Hussain FM. The Role of the core polarization on C2and C4 form factor, Rom. Jour. Phys. 2014 May; 59:95-11.

Majeed FA, Obaid SM. Nuclear structure study of 22, 24Ne and 24Mg nuclei. Rev. Mex. Fis. 2019Apr;65: 159-9.

Hameed BS. The Nuclear Structure for Exotic Neutron-Rich of 42,43,45,47K Nuclei. Baghdad Sci. J. 2020 Apr;13(1):146-9.

Skyrme THR. The effective nuclear potential. Nucl. Phys. 1959 Oct; 9:615-20.

Ghafouri M, Sadeghi H, Torkiha M. Self-consistent description of the SHFB equations for 112Sn. Results Phys. 2018 Mar;8: 734-10.

Baldik R, Dombayci A. Investigation of the production of 68Ga using pre-equilibrium models. Appl. Radiat. Isot., 2016 May; 113:10-7.

Sarriguren P, Moreno O, de Guerra E M , Kadrev D N, Antonov A N, and Gaidarov M K. Elastic Magnetic Electron Scattering from odd-A Nuclei. J. Phys.: Conf. Ser. 2020 May; 1555: 012001-8.

Brown BA, Rae WDM. The shell-model code NuShellX@ MSU. Nucl. Data Sheets. 2014 Jun; 120: 115-4.

Tassie LJ. A Model of Nuclear Shape Oscillations for g-Transitions and Electron Excitation. Aust. J. Phys. 1965 Aug; 9(4): 407-12.

Heisenberg J, McCarthy JS, Sick I. Inelastic electron scattering from several Ca, Ti and Fe isotopes. Nucl. Phys. A 1971; 164(2): 353-366.

Mooy RBM and Glaudemans PWM. Electron scattering form factors for fp-shell nuclei. Nucl. Phys. A 1971 May; 438: 461-21.

Vries HD, Jager CW, De Vries C. Nuclear charge-density-distribution parameters from elastic electron scattering. At. Data Nucl. Data Tables. 1987 Sep; 36:459-41.

Fricke G, Bernhardt Heilig CK, Schaller LA, Schellenber LG, Shera EB and De Jager CW. Nuclear Ground State Charge Radii from Electromagnetic Interactions. At. Data Nucl. Data Tables. 1995 Jul; 60:177-108.