Disentangling effects of nuclear structure in heavy element formation

D. J. Hinde; R. G. Thomas; R. Du Rietz; A. Diaz-Torres; M. Dasgupta; M. L. Brown; M. Evers; L. R. Gasques; R. Rafiei; M. D. Rodriguez

doi:10.1103/PhysRevLett.100.202701

Disentangling effects of nuclear structure in heavy element formation

D. J. Hinde, R. G. Thomas, R. Du Rietz, A. Diaz-Torres, M. Dasgupta, M. L. Brown, M. Evers, L. R. Gasques, R. Rafiei, M. D. Rodriguez

Research output: Contribution to journal › Article › peer-review

67 Citations (Scopus)

Abstract

Forming the same heavy compound nucleus with different isotopes of the projectile and target elements allows nuclear structure effects in the entrance channel (resulting in static deformation) and in the dinuclear system to be disentangled. Using three isotopes of Ti and W, forming Cm232, with measurement spanning the capture barrier energies, alignment of the heavy prolate deformed nucleus is shown to be the main reason for the broadening of the mass distribution of the quasifission fragments as the beam energy is reduced. The complex, consistently evolving mass-angle correlations that are observed carry more information than the integrated mass or angular distributions, and should severely test models of quasifission.

Original language	English
Article number	202701
Journal	Physical Review Letters
Volume	100
Issue number	20
DOIs	https://doi.org/10.1103/PhysRevLett.100.202701
Publication status	Published - 20 May 2008

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10.1103/PhysRevLett.100.202701

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AU - Hinde, D. J.

AU - Thomas, R. G.

AU - Du Rietz, R.

AU - Diaz-Torres, A.

AU - Dasgupta, M.

AU - Brown, M. L.

AU - Evers, M.

AU - Gasques, L. R.

AU - Rafiei, R.

AU - Rodriguez, M. D.

PY - 2008/5/20

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N2 - Forming the same heavy compound nucleus with different isotopes of the projectile and target elements allows nuclear structure effects in the entrance channel (resulting in static deformation) and in the dinuclear system to be disentangled. Using three isotopes of Ti and W, forming Cm232, with measurement spanning the capture barrier energies, alignment of the heavy prolate deformed nucleus is shown to be the main reason for the broadening of the mass distribution of the quasifission fragments as the beam energy is reduced. The complex, consistently evolving mass-angle correlations that are observed carry more information than the integrated mass or angular distributions, and should severely test models of quasifission.

AB - Forming the same heavy compound nucleus with different isotopes of the projectile and target elements allows nuclear structure effects in the entrance channel (resulting in static deformation) and in the dinuclear system to be disentangled. Using three isotopes of Ti and W, forming Cm232, with measurement spanning the capture barrier energies, alignment of the heavy prolate deformed nucleus is shown to be the main reason for the broadening of the mass distribution of the quasifission fragments as the beam energy is reduced. The complex, consistently evolving mass-angle correlations that are observed carry more information than the integrated mass or angular distributions, and should severely test models of quasifission.

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Disentangling effects of nuclear structure in heavy element formation

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