Mechanisms Suppressing Superheavy Element Yields in Cold Fusion Reactions

K. Banerjee; D. J. Hinde; M. Dasgupta; E. C. Simpson; D. Y. Jeung; C. Simenel; B. M. A. Swinton-Bland; E. Williams; I. P. Carter; K. J. Cook; H. M. David; Ch. E. Düllmann; J. Khuyagbaatar; B. Kindler; B. Lommel; E. Prasad; C. Sengupta; J. F. Smith; K. Vo-Phuoc; J. Walshe; A. Yakushev

doi:10.1103/physrevlett.122.232503

Mechanisms Suppressing Superheavy Element Yields in Cold Fusion Reactions

K. Banerjee(Australian National University), D. J. Hinde(Australian National University), M. Dasgupta(Australian National University), E. C. Simpson(Australian National University), D. Y. Jeung(Australian National University), C. Simenel(Australian National University), B. M. A. Swinton-Bland(Australian National University), E. Williams(Australian National University), I. P. Carter(Australian National University), K. J. Cook(Australian National University), H. M. David(GSI Helmholtz Centre for Heavy Ion Research), Ch. E. Düllmann(GSI Helmholtz Centre for Heavy Ion Research), J. Khuyagbaatar(Helmholtz Institute Mainz), B. Kindler(GSI Helmholtz Centre for Heavy Ion Research), B. Lommel(GSI Helmholtz Centre for Heavy Ion Research), E. Prasad(Australian National University), C. Sengupta(Australian National University), J. F. Smith(Australian National University), K. Vo-Phuoc(Australian National University), J. Walshe(Australian National University), A. Yakushev(GSI Helmholtz Centre for Heavy Ion Research)

Physical Review Letters

June 14, 2019

10.1103/physrevlett.122.232503

Cited by 49Open Access

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Abstract

Superheavy elements are formed in fusion reactions which are hindered by fast nonequilibrium processes. To quantify these, mass-angle distributions and cross sections have been measured, at beam energies from below-barrier to 25% above, for the reactions of ^{48}Ca, ^{50}Ti, and ^{54}Cr with ^{208}Pb. Moving from ^{48}Ca to ^{54}Cr leads to a drastic fall in the symmetric fission yield, which is reflected in the measured mass-angle distribution by the presence of competing fast nonequilibrium deep inelastic and quasifission processes. These are responsible for reduction of the compound nucleus formation probablity P_{CN} (as measured by the symmetric-peaked fission cross section), by a factor of 2.5 for ^{50}Ti and 15 for ^{54}Cr in comparison to ^{48}Ca. The energy dependence of P_{CN} indicates that cold fusion reactions (involving ^{208}Pb) are not driven by a diffusion process.

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