Effect of shell structure on the fission of sub-lead nuclei

Scamps, Guillaume; Simenel, C.

doi:10.1103/physrevc.100.041602

Cited by 72 publications

(55 citation statements)

References 85 publications

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“…For this system the Z = 82 shell effect does not seem to play a major role contrary to previous TDHF observations for the Ca+U target projectile combinations. We also point out that mass-angle correlations could be used to experimentally isolate the fragments influenced by N = 56 octupole shell gaps [100,101,54]. We also find that more peripheral collisions are centered about the proton number Z = 40 confirming similar observations from past calculations [37] that the 100 Zr region plays an important role in determining the lighter fragments due to the existence of strongly bound highly deformed Zr isotopes in this region [102].…”

Section: Deformed Shell Effects In Quasifissionsupporting

confidence: 85%

Quasifission Dynamics in Microscopic Theories

Godbey

Umar

2020

Front. Phys.

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In the search for superheavy elements quasifission reactions represent one of the reaction pathways that curtail the formation of an evaporation residue. In addition to its importance in these searches quasifission is also an interesting dynamic process that could assist our understanding of many-body dynamical shell effects and energy dissipation thus forming a gateway between deep-inelastic reactions and fission. This manuscript gives a summary of recent progress in microscopic calculations of quasifission employing time-dependent Hartree-Fock (TDHF) theory and its extensions.

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Section: Deformed Shell Effects In Quasifissionsupporting

confidence: 85%

Quasifission Dynamics in Microscopic Theories

Godbey

Umar

2020

Front. Phys.

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“…The spatial electron localization function (ELF) was originally introduced in the context of electronic Hartree-Fock (HF) studies to characterize shell structure in atoms and chemical bonds in molecules [9][10][11][12][13][14]. In nuclear structure research, the nucleon localization function (NLF) turned out to be a useful tool for the identification of clusters in light nuclei [15][16][17] and nuclear reactions [18]; formation of fragments in fission [19][20][21][22][23]; and nuclear pasta phases in the inner crust of neutron stars [16]. Compared with nucleonic distributions that are fairly constant in the nuclear interior, the NLF more effectively quantifies nuclear configurations through its characteristic oscillating pattern due to shell effects.…”

Section: Introductionmentioning

confidence: 99%

Nucleon localization function in rotating nuclei

Chen

Zhang

et al. 2020

Phys. Rev. C

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Background: An electron localization function was originally introduced to visualize in positional space bond structures in molecules. It became a useful tool to describe electron configurations in atoms, molecules, and solids. In nuclear physics, a nucleon localization function (NLF) has been used to characterize cluster structures in light nuclei, formation of fragments in fission, and pasta phases appearing in the inner crust of neutron stars. Purpose: We use the NLF to study the nuclear response to fast rotation. Methods: We generalize the NLF to the case of nuclear rotation. The extended expressions involve both timeeven and time-odd local particle and spin densities and currents. Since the current density and density gradient contribute to the NLF primarily at the surface, we propose a simpler spatial measure given by the kinetic-energy density. Illustrative calculations for the superdeformed yrast band of 152 Dy were carried out by using the cranked Skyrme-Hartree-Fock method. We also employed the cranked harmonic-oscillator model to gain insights into spatial patterns revealed by the NLF at high angular momentum. Results: In the case of a deformed rotating nucleus, several NLFs can be introduced, depending on the definition of the spin-quantization axis, direction of the total angular momentum, and self-consistent symmetries of the system. Contributions to the NLF from the current density, spin-current tensor density, and density gradient terms are negligible in the nuclear interior. The oscillating pattern of the simplified NLF can be explained in terms of a constructive interference between kinetic-energy and particle densities. The characteristic nodal pattern seen in the NLF in the direction of major axis of a rotating nucleus comes from single-particle orbits carrying large aligned angular momentum. The variation of the NLF along the minor axis of the nucleus can be traced back to deformation-aligned orbits. Conclusions: The NLF allows a simple interpretation of the shell structure evolution in the rotating nucleus in terms of the angular-momentum alignment of individual nucleons. We expect that the NLF will be very useful for the characterization and visualization of other collective modes in nuclei and time-dependent processes.

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“…However, due to strong Coulomb interaction, and the presence of a neck between the fragments in which strong interaction between the fragments is still present, both pre-fragments are deformed with a strong quadrupole shape or a strong octupole deformation. As a result, deformed shell effects are expected to dominate [3,4].…”

Section: Introductionmentioning

confidence: 99%

“…To test the universality of the effect of octupole shell structure on the asymmetry of fission, neutron-rich mercury isotopes have been studied with a similar approach [4]. The 180 Hg case is particular since it was expected to fission symmetrically leading to two 90 Zr which is a magic nuclei with N = 50.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Effect of Octupole Correlations on Fission of Light Nuclei

Scamps

Simenel

2020

Proceedings of 13th International Conference on Nucleus-Nucleus Collisions

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Fission of 180 Hg produces mass asymmetric fragments which are expected to be influenced by deformed shell-effects at N = 56 in the heavy fragment and Z = 34 in the light fragment [G. Scamps and C. Simenel, arXiv:1904.01275 (2019)]. To investigate both shell-effects and to determine which one has the main influence on the asymmetry in the region of the 180 Hg, we produce a systematic of Constraint-Hartree-Fock calculations in nuclei with similar N/Z ratio than the 178 Pt. It is found that N = 56 determines the asymmetry of systems in this region of the nuclear chart.

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Effect of shell structure on the fission of sub-lead nuclei

Cited by 72 publications

References 85 publications

Quasifission Dynamics in Microscopic Theories

Quasifission Dynamics in Microscopic Theories

Nucleon localization function in rotating nuclei

Effect of Octupole Correlations on Fission of Light Nuclei

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