Tasleem A. Siddiqui scite author profile

The superheavy nuclei have been examined systematically in the region 158 ⩽ N ⩽ 218, 162 ⩽ N ⩽ 212 for Z = 122 and 128, respectively. The explicit density-dependent meson-exchange (DD-ME) and point-coupling (DD-PC) models within the framework of covariant density functional theory (CDFT) have been used to study the structural and decay properties of the isotopic series which includes the separable form of a finite range of pairing interaction. From the potential energy curves, the ground state properties of nuclei are predicted. Due to the importance of the shell effect in the superheavy region, the Strutinsky shell correction method has been employed for a better understanding of the extra stability of nuclei. The results from neutron pairing energy, two-neutron separation energy (S 2n ), single-particle energy levels, and total shell-correction energy strongly support N = 168, 174, and 178 as deformed neutron-magic numbers from both the force parameter, in both the isotopic series. N = 172 and 184 are predicted as spherical magic with DD-ME2 interaction in the Z = 122 isotopic series. Using three different semi-empirical approaches named UNIV2, SemFIS2, and ImSahu, the α-decay properties are studied and compared with available experimental data, FRDM2012 and the WS4 mass model. The stability of synthesized superheavy nuclei can be determined by comparing spontaneous fission half-lives with α-decay half-lives.

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Microscopic description of structural, surface, and decay properties of Z=124, 126 superheavy nuclei

Siddiqui

Quddus

Ahmad

et al. 2021

Nuclear Physics A

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Socio-Economic Correlates of Outpatient Care in a Factor Analytic Framework

Purohit

Siddiqui

1995

Journal of Health & Social Policy

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Relativistic Mean Field Description of Iodine Nuclei in the Mass Region $${123\leqslant A\leqslant 133}$$

2022

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Relativistic Mean Field Study of SM Isotopes with FTBCS Approach

Karim¹,

Siddiqui²,

Ahmad³

2015

IJRAP

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