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Measurement of the Survival Probabilities for Hot Fusion Reactions

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 نشر من قبل Walter Loveland
 تاريخ النشر 2014
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We have studied the fission-neutron emission competition in highly excited $^{274}$Hs (Z=108) (where the fission barrier is due to shell effects) formed by a hot fusion reaction. Matching cross bombardments ($^{26}$Mg + $^{248}$Cm and $^{25}$Mg + $^{248}$Cm) were used to identify the properties of first chance fission of $^{274}$Hs. A Harding-Farley analysis of the fission neutrons emitted in the $^{25,26}$Mg + $^{248}$Cm was performed to identify the pre- and post-scission components of the neutron multiplicities in each system. ($Gamma$$_{n}$/$Gamma$$_{t}$) for the first chance fission of $^{274}$Hs (E$^{ast}$ = 63 MeV) is 0.89 $pm$ 0.13, i.e., $sim$ 90 $%$ of the highly excited nuclei survive.The high value of that survival probability is due to dissipative effects during de-excitation. A proper description of the survival probabilities of excited superheavy nuclei formed in hot fusion reactions requires consideration of both dynamic and static (shell-related) effects.



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