Bubble structure in magic nuclei

Saxena, Gaurav; Kumawat, M.; Kaushik, M.; Jain, S. K.; Aggarwal, Mamta

doi:10.1016/j.physletb.2018.08.076

Cited by 49 publications

(50 citation statements)

References 53 publications

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“…It is obvious that the bubble structure for the Zr isotopes does not have a noticeable effect on NST. The isospin for the nuclei with constant Z configurations like the Zr isotopes and quantum shell effects may be investigated by new studies because the quantum shell effects strongly influence the bubble structure in lighter nuclei, contrary to heavy/superheavy nuclei, due to coherence between the strong attractive nucleon-nucleon force and the large repulsive Coulomb interaction [42]. To assess the ability of the employed SHF approach for the SkM* parameter, we have compared the binding energies of the Zr isotopes with those of experimental and theoretical results from FRDM, AME and RMFT [24][25][26] in Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Notably, the variation in density is related to quantal effects which fill the single-particle levels near the Fermi energy. This situation leads to sensitivity in the depletion fraction to the quantal effects, and the s orbitals (l = 0) are exclusively a non-zero wave function at the center, whereas there is no contribution to density at the center in the non-zero l orbitals [42]. The detection of depletion fraction for the neutron density at the center of nuclei may be provided by bubble parameters:…”

Section: Theoretical Frameworkmentioning

confidence: 99%

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Neutron Skin, Central Depletion, Neutron–Proton Interaction Effects and 2pF Parameterization for Zr in Neutron Stars

Artun

2020

Braz J Phys

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A study of the neutron skin thicknesses, central depletions and neutron-proton interactions for the isotopic chain of Zr (32 ≤ N ≤ 98) with even-even and even-odd nuclei is carried out within the framework of the Skyrme-Hartree-Fock approach. The neutron skin thicknesses are calculated by three different methods, one of which is the hard spheres, and the neutron thicknesses including surface and bulk parts are investigated for Zr isotopes as a function of the relative neutron excess I = (N − Z)/A. For that purpose, the level density distributions and 2pF parameters are calculated, and theoretical methods are used to obtained the residual and average neutron-proton interactions (δV np , δ np), in addition to the single-particle energy levels for j ¼ l∓ 1 2 states, the charge form factors F ch (k), and the pairing, Fermi and binding energies. The importance of the obtained results is discussed in terms of the quantum effects, the Coulomb repulsion and neutron-neutron interaction.

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Section: Resultsmentioning

confidence: 99%

Section: Theoretical Frameworkmentioning

confidence: 99%

Neutron Skin, Central Depletion, Neutron–Proton Interaction Effects and 2pF Parameterization for Zr in Neutron Stars

Artun

2020

Braz J Phys

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“…The calculations in the relativistic mean-field approach [17,[54][55][56][57][58] have been carried out using the model Lagrangian density with nonlinear terms both for the σ and ω mesons along with NL3* parametrization [59]. The corresponding Dirac equations for nucleons and Klein-Gordon equations for mesons obtained with the mean-field approximation are solved by the expansion method on the widely used axially deformed Harmonic-Oscillator basis [60,61].…”

Section: Theoretical Frameworkmentioning

confidence: 99%

Structural properties and α-decay chains of transfermium nuclei (101≤Z≤110)

Singh

Sharma

Sharma³

et al. 2021

Nuclear Physics A

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Transfermium nuclei (101≤Z≤110) are investigated thoroughly to describe structural properties viz. deformation, radii, shapes, magicity, etc. as well as their probable decay chains. These properties are explored using relativistic mean-field (RMF) approach and compared with other theories along with available experimental data. Neutron numbers N=152 and 162 have come forth with a deformed shell gap whereas N=184 is ensured as a spherical magic number. The region with N>168 bears witness of the phenomenon of shape transition and shape coexistence for all the considered isotopic chains. Experimental α-decay half-lives are compared with our theoretical halflives obtained by using various empirical/semi-empirical formulas. The recent formula proposed by Manjunatha et al., which results best among the considered 10 formulas, is further modified by adding asymmetry dependent terms (I and I 2). This modified Manjunatha formula is utilized to predict probable α-decay chains that are found in excellent agreement with available experimental data.

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“…We use relativistic mean-field approach (RMF) [29][30][31][32][33][34][35][36][37][38] for the present study where the various parameterizations/variants of the RMF models have been used for the calculations. The first variant of RMF comprises of the following model Lagrangian density with nonlinear terms for the σ and ω mesons [36,[39][40][41];…”

Section: Theoretical Formulationmentioning

confidence: 99%

“…The nucleus 40 Mg, with magic neutron number N=28, is the most neutron-rich isotope of Mg accessible experimentally [1]. The experimental observation of γ-ray transitions in 40 Mg [2] indicate that the structure of 40 Mg is different from the neighbouring isotopes 36,38 Mg in contrast to the theoretical expectations [2]. This could possibly be due to two weakly bound valence neutrons at the Fermi surface that may couple to the classically forbidden continuum where the nucleon binding is dominated by pairing correlations rather than the mean-field of core to form a halo [3].…”

Section: Introductionmentioning

confidence: 99%

Collapse of N$=$28 magicity in exotic $^{40}$Mg -- Probe of deformed halo and 2n-radioactivity at Mg neutron drip-line

Saxena,

Kumawat,

Sharma

et al. 2021

Preprint

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The exotic phenomenon of two-neutron halos and 2n-radioactivity are explored in the neutron-rich 40,42,44 Mg by employing various variants of the relativistic mean-field approach. The extended tail of spatial density distributions including the enhanced neutron radii and skin thickness, pairing correlations, single-particle spectrum and wave functions predict 40,42,44 Mg to be strong candidates for deformed neutron halos. Weakening of magicity at N=28 plays a significant role in the existence of a weakly bound halo in 40 Mg which is currently the heaviest isotope of Mg accessible experimentally. Large deformation, mixing of f-p shell Nilsson orbitals and the valence neutron occupancy of p-states leads to a reduced centrifugal barrier and broader spatial density distributions that favour 2n-radioactivity in 42,44 Mg.

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Bubble structure in magic nuclei

Cited by 49 publications

References 53 publications

Neutron Skin, Central Depletion, Neutron–Proton Interaction Effects and 2pF Parameterization for Zr in Neutron Stars

Neutron Skin, Central Depletion, Neutron–Proton Interaction Effects and 2pF Parameterization for Zr in Neutron Stars

Structural properties and α-decay chains of transfermium nuclei (101≤Z≤110)

Collapse of N$=$28 magicity in exotic $^{40}$Mg -- Probe of deformed halo and 2n-radioactivity at Mg neutron drip-line

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