C. Karthika scite author profile

The shell structure of a nucleus is important to study their observed characteristic features. The classic magic numbers are successful in explaining the nuclear properties for nuclei lying near the stability line. The advent of radioactive ion beam facilities has permitted to examine nuclei in their extreme proton to neutron ratio. The light exotic nuclei were found to exhibit unique shell closure behaviour which is different from the medium mass nuclei near the stability line. The two nucleon separation energy difference systematics was used as a probe to study the magic character of light nuclei. New proton and neutron magic numbers were predicted among the available even Z isotopes and even N isotones. For certain systems, the classic magic numbers were found to be non-magic, while for some systems the magic property is retained even at the drip lines. The shell closure behaviour predicted is found to depend on the version of the mass table.

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Mirror nuclei of 1n/2n halo systems as 1p/2p emitters

Karthika

Balasubramaniam

2019

Phys. Rev. C

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Signature of magic numbers in light exotic nuclei

Karthika¹,

Balasubramaniam²

2021

Int. J. Mod. Phys. E

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The advent of technology widened the study of shell closure for nuclei lying far away from the stability line. The classic shell closures are observed to be valid for nuclei near the stability line. The light exotic nuclei exhibit unique behavior compared to those of stable ones. The objective of this work is to study the shell closure in light nuclei near the neutron drip-line to the proton drip-line region. The systematics of two nucleon separation energy difference ([Formula: see text]) between calculated and experimental data are taken as a tool to study the shell closure of light nuclei. Nucleon separation energy is determined using the liquid drop model (LDM) expression with modified asymmetry and pairing energy terms. The light mass numbered isotopes and isotones as a function of even neutron and even proton numbers were considered for this work. The shell structure predicted by [Formula: see text] systematics is compared with the first excitation energy [Formula: see text]. The modified LDM is successful in identifying the shell structure properties of light nuclei in exotic region. The study supports the emergence of new shell closure and the disappearance of existing classic shell closure for both neutron and proton numbers. The shell structure predicted by [Formula: see text] systematics for isotopes (isotones) of magic nucleon number [Formula: see text] was in agreement with the results of [Formula: see text] analysis.

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Scission point model applied to $$^{181} \hbox {Re}^{*}$$ formed in $$^{12}{} \mathbf{C}+^{169}$$Tm reaction

Karthika

Balasubramaniam

2020

Eur. Phys. J. A

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C. Karthika

Scission point model for the mass distribution of ternary fission

Appearance / Disappearance of Magic Number in Light Nuclei

Mirror nuclei of 1n/2n halo systems as 1p/2p emitters

Signature of magic numbers in light exotic nuclei

Scission point model applied to $$^{181} \hbox {Re}^{*}$$ formed in $$^{12}{} \mathbf{C}+^{169}$$Tm reaction

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