Properties of nuclei, synthesis and stability of heavy nuclei

^{last updated: December 2014}

Possibility of existence/stability/structure of super-heavy nuclei (in connection with experiments run in Dubna and in GSI, soon also at GANIL).
Properties (masses, decay paths) of nuclei far from stability (in connection with experiments run in GSI and in Jyväskylä).
Nuclei exotic states (third minima, K isomers).
Evaluation and analysis of nuclei masses currently measured in GSI.

Masses and deformations in ground states and saddle points for super-heavy nuclei from the 98<Z<126 and 134<N<192 region (including ground states for odd nuclei) were determined. Alpha decay energies were calculated. Two pairing accounting methods were used: blocking and adding quasi-particle energy. Discrepancies between theoretical calculations and experimental data turned out to be smaller in the super-heavy nuclei region than in the fitting region.
The microscopic/macroscopic method applied in 8 dimensions (an unprecedented approach) resulted in a low value (360 keV) of the 3^rd barrier, which was in line with old experimental results (Blons et al.). Unclear current experimental situations was pointed out.
Fission barriers and stability of super-heavy nuclei Z ≥ 126 were predicted.

Several possible structural effects that might inhibit alpha decay and explain some discrepancies between experimental data and theoretical predictions were identified.
Calculated masses were used to estimate cross sections in hot fusion reactions leading to synthesis of Z=119 and Z=120 super-heavy elements.
An original method to correct the time necessary for ^181,183Lu, ^185,186Hf, ^187,188Ta, ¹⁹¹W and ^192,193Re ions to travel around the ESR-GSI ring was worked out. Accuracy in measurements of masses of ^189,190W and ¹⁹⁵Os nuclei was improved.
²¹²Bi nucleus isomeric state was analysed.

The obtained cross sections for production of several super-heavy elements are necessary to plan reactions of synthesis of the most heavy nuclei on Earth.
The developed method to correct ESR-GSI ring travelling times will be used to improve accuracy in measurements of masses conducted in GSI.
Theoretical predictions of nuclei masses and alpha decay energies will soon be verified experimentally. Depth of the 3^rd minimum in Th-232 will soon be experimentally verified within the framework of the ELI (Extreme Light Infrastructure) European programme.

_{This page edited by: Marek Pawłowski}

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