Microscopic study of nuclear structure of odd-odd <sup>128</sup>–<sup>138</sup>I nuclei within the framework of projected shell model for positive- and negative-parity states

Kumar, Vikesh; Dhiman, Shashi K.

doi:10.1142/s0217732320502430

Cited by 3 publications

(1 citation statement)

References 43 publications

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“…These studies aim to address all these properties, which are: shape evolution, shape coexistence, quadrupole deformation parameter β 2 , single-particle energy levels, the binding energy per nucleon, pairing energy, one-neutron separation energy, two-neutron separation energy, nuclear charge radius, neutron rms radius, proton rms radius, and neutron skin thickness. In our previous paper [14], we have done microscopic studies of the nuclear structure of 128−138 I nuclei within the framework of the projected shell model. Iodine is a potential candidate after shell closure Z=50, having an atomic number of Z=53.…”

Section: Introductionmentioning

confidence: 99%

Microscopic study of shape evolution and ground-state properties of Iodine isotopes

Kumar¹,

Kumar²,

Thakur³

et al. 2020

Phys. Scr.

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In this paper, we investigated the shape evolution and ground-state properties of 108−144I isotopes using Hartree–Fock-Bogoliubov Model while employing the axially deformed single-particle harmonic oscillator basis for the expansion of quasiparticle wave functions. We have used SKP and UNEDF2 models to perform the theoretical calculations. We have presented the shape evolution and final values of the quadrupole deformation parameter β 2 of iodine isotopes. We have used the final values of the β 2 for studying the ground-state properties of the iodine isotopic chain. The investigated ground-state properties are the nuclear electric quadrupole moment, single-particle energy levels, the binding energy per nucleon, pairing energy, one-neutron separation energy, two-neutron separation energy, nuclear charge radius, neutron rms radius, proton rms radius, and neutron skin thickness. After using the SKP parameterization on 109I, we have observed the shape coexistence of prolate and oblate shape. Similarly, after using the UNEDF2 parameterization on 110I, 112I, 114I, 115I, 116I, 117I, 118I, and 119I, we discover the shape coexistence of prolate and oblate shape.

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Section: Introductionmentioning

confidence: 99%

Microscopic study of shape evolution and ground-state properties of Iodine isotopes

Kumar¹,

Kumar²,

Thakur³

et al. 2020

Phys. Scr.

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The microscopic studies of the even-even 12−28O, 34−60Ca, 48−80Ni, and 100−134Sn using covariant density functional theory

Kumar

Thakur

et al. 2022

Nuclear Physics A

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Microscopic study of shape evolution and some important ground state properties of ^190–210Au isotopes

Kumar

Thakur

et al. 2021

Int. J. Mod. Phys. E

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In this paper, we have examined the nuclear structural properties of [Formula: see text]Au isotopes within the framework of the Hartree–Fock–Bogoliubov Model. For the theoretical calculations, we have used the UNEDF2 and SKP interactions. The studies include the shape evolution, quadrupole deformation parameter [Formula: see text], nuclear electric quadrupole moment Q(b), single-particle energy levels, the binding energy per nucleon, nuclear charge radius, neutron rms radius, proton rms radius and neutron skin thickness. To analyze the accuracy of our theoretical results, we have presented the comparative analysis with experimental data and finite-range droplet model calculations. The adequate resemblance with experimental data is supporting our studies. We observe the oblate-prolate shape coexistence for [Formula: see text]Au, [Formula: see text]Au and [Formula: see text]Au using the UNEDF2 interaction.

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Microscopic study of nuclear structure of odd-odd ¹²⁸–¹³⁸I nuclei within the framework of projected shell model for positive- and negative-parity states

Cited by 3 publications

References 43 publications

Microscopic study of shape evolution and ground-state properties of Iodine isotopes

Microscopic study of shape evolution and ground-state properties of Iodine isotopes

The microscopic studies of the even-even 12−28O, 34−60Ca, 48−80Ni, and 100−134Sn using covariant density functional theory

Microscopic study of shape evolution and some important ground state properties of ^190–210Au isotopes

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Microscopic study of nuclear structure of odd-odd 128–138I nuclei within the framework of projected shell model for positive- and negative-parity states

Cited by 3 publications

References 43 publications

Microscopic study of shape evolution and ground-state properties of Iodine isotopes

Microscopic study of shape evolution and ground-state properties of Iodine isotopes

The microscopic studies of the even-even 12−28O, 34−60Ca, 48−80Ni, and 100−134Sn using covariant density functional theory

Microscopic study of shape evolution and some important ground state properties of 190–210Au isotopes

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Product

Resources

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Microscopic study of nuclear structure of odd-odd ¹²⁸–¹³⁸I nuclei within the framework of projected shell model for positive- and negative-parity states

Microscopic study of shape evolution and some important ground state properties of ^190–210Au isotopes