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An alpha decay study of superheavy nuclei within a Coulomb and proximity potential model including a Q-value dependent surface diffuseness parameter

Ananya Babu

Department of Physics, ITM College of Arts and Science, Mayyil, Kerala 670602, India

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Lisha Damodaran

Department of Physics, Government Brennen College, Dharmadam, Kerala 670106, India

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T. P. Suresh

Department of Physics, Government Brennen College, Dharmadam, Kerala 670106, India

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, and

K. Prathapan

https://orcid.org/0000-0003-3451-7713

Department of Physics, Government Brennen College, Dharmadam, Kerala 670106, India

E-mail Address: prathapankodolipram@gmail.com

Corresponding author.

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https://doi.org/10.1142/S0218301324500319Cited by:1 (Source: Crossref)

Abstract

Using the Coulomb and Proximity Potential Model (CPPM) and a Q-value dependent surface diffuseness parameter in the proximity potential, the alpha decay half-lives of 75 experimentally synthesized superheavy nuclei were determined. Comparisons are made between the obtained results and experimentally determined alpha decay half-lives, as well as the predictions of Yang et al.’s recent study [Nucl. Phys. A 1014 (2021) 122250], which is based on the Unified Fission Model (UFM) with a new preformation parameter. The lowest standard deviation of 0.621 is obtained for CPPM calculations with Q-value-dependent surface diffuseness parameter. The calculation is extended further to estimate the alpha decay half-lives ${of}^{284 - 315}$ 119 and $^{287 - 316}$ 120 superheavy isotopes and compared with the predictions of UFM. Finally, the results of the calculations are compared to the predictions of the UDL formula [Phys. Rev. Lett. 103 (2009) 072501] and the modified Hutsukawa formula [Nucl. Part. Phys. Proc. 339 (2023) 92].

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