Utilizing the Quark-Like Model (QLM) to Determine the $$Q_{\beta }^{ - }$$-Value in the Range 2 ≤ Z ≤ 97

Qasim, Aws Tariq; Al-jomaily, Firas Mohammed Ali

doi:10.1007/s40995-020-00969-2

Cited by 2 publications

(1 citation statement)

References 42 publications

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“…In order to determine the accuracy of the two equation ( 7),(1 ( 2 and compare them with the experimental results, the standard deviation was calculated [23].…”

Section: Determine the Standard Deviation Of The Proposed Modelsmentioning

confidence: 99%

Adding a correction terms for the shell of the Liquid Drop Model and the Quark-Like Model

aldawdy

Al-jomaily

2023

Arab Journal of Nuclear Sciences and Applications

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This paper aims to add a corrective term to Liquid Drop Model (LDM) and Quark -Like Model (QLM), which is the term for closed shells of magic nuclei. This was done by relying on valence nucleons. Fitting to the terms volume, surface, Coulomb repulsion, asymmetry, pairing and shell term in LDM was performed using the least-square method LSM by designing a code in Fortran 95 for 261 magic nuclei within the range (2≤Z≤92), this correct and balance nuclear binding energy values, especially for magic nuclei, with experimental values. A fit of the QLM has also been made in order to correct the values of the nuclear binding energy. The standard deviation (σ) was used as a statistical tool to determine the extent to which the models can be adopted to explain the behavior of magic nuclei, in addition to the high accuracy in determining the experimental nuclear binding energy. The values of the standard deviation are σ= 0.144 and σ= 0.84 for the updated formulas of the Generalized Liquid Drop Mode (GLDM) and the Generalized Quark Like Model (GQLM) respectively.

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“…In order to determine the accuracy of the two equation ( 7),(1 ( 2 and compare them with the experimental results, the standard deviation was calculated [23].…”

Section: Determine the Standard Deviation Of The Proposed Modelsmentioning

confidence: 99%

Adding a correction terms for the shell of the Liquid Drop Model and the Quark-Like Model

aldawdy

Al-jomaily

2023

Arab Journal of Nuclear Sciences and Applications

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Improving the Phenomenological Version of Alpha Decay Energy of Heavy and Super Heavy Nuclei

Al-jomaily

2021

J. Phys.: Conf. Ser.

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The nuclear binding energy calculated by the quark model has been used in the current research to quantify alpha decay energy (Qα- value). The research dealt with the odd-even and even - even type of heavy and super-heavy nuclei within the range (78≤ Z ≤ 118). By knowing the number of Z and N for a given nucleus, regardless of its mass, it became possible to calculate the energy of alpha decay. By correlating the experimental nuclear binding energy values of the parent nucleus and its daughters with the theoretically computed values, the quark model was adapted. Graphically extracted calibration equations have been used to produce a modern version of the alpha decay energy by linear and logarithmic matching. As essential statistical instruments, the square root rate and standard deviation were determined to show the utility of adjusted models in testing decay energy and nuclear binding energy. The analyses revealed that the experimental results have been approved.

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Utilizing the Quark-Like Model (QLM) to Determine the $$Q_{\beta }^{ - }$$-Value in the Range 2 ≤ Z ≤ 97

Cited by 2 publications

References 42 publications

Adding a correction terms for the shell of the Liquid Drop Model and the Quark-Like Model

Adding a correction terms for the shell of the Liquid Drop Model and the Quark-Like Model

Improving the Phenomenological Version of Alpha Decay Energy of Heavy and Super Heavy Nuclei

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