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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.
Published Online First 20/1/2022
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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 [email protected] 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.