A semiclassical description of rapidly rotating nuclei

doi:10.1016/0375-9474(93)90562-C

Nuclear Physics A

Volume 557, 31 May 1993, Pages 459-468

https://doi.org/10.1016/0375-9474(93)90562-C Get rights and content

Abstract

A brief review is made of a recent semiclasslcal treatment of nuclear rotation where explicit and simple expressions for relevant densities and moments of inertia in terms of the matter densities of rotating nuclei, have been derived within the framework of the Extended Thomas-Fermi approximation upon using a Skyrme nucleon-nucleon effective Interaction. As a result of preliminary non-fully self-consistent calculations, the moments of inertia are found not to deviate very much from the rigid body ansatz. since corrective terms arising from the orbital motion and the spin degrees of freedom are found to roughly cancel each other. We particularly develop here a proof of equivalence In our routhian approach, of kinematic and dynamic moments of Inertia. As a testing case we have also extended the formalism to the translational case In the “pushing model” approach and found the right translational mass.

References (13)

M. Brack et al.
Phys. Rep.
(1985)
D.J. Thouless et al.
Nucl. Phys.
(1962)
B. Grammaticos et al.
Ann. Phys.
(1979)
B. Grammaticos et al.
Ann. Phys.
(1980)
J. Bartel et al.
Nucl. Phys.
(1982)
G.A. Pik-Pichak
Sov. J. Nucl. Phys.
(1968)
Yad. Flz.
(1967)
J. Dabrowski
Phys. Lett.
(1975)
K. Neergaard et al.
Nucl. Phys.
(1976)
I.N. Mikhailov et al.
Sov. J. Part. Nucl.
(1977)
Fiz. Elem. Chastits At. Yadra
(1977)

There are more references available in the full text version of this article.

Cited by (6)

Nuclear Data Sheets for A = 214
2009, Nuclear Data Sheets
Rotations in nuclei - a semiclassical description
1994, Nuclear Physics, Section A
An explicit formulation of extended Thomas-Fermi density functionals relevant to a microscopic description of rotating nuclei within the Skyrme Hartree-Fock formalism, is presented up to order $h ̵^{2}$ . Simple analytical expressions have been obtained for the dynamical moments of inertia within this semiclassical framework. Phenomena identical to Landau orbital diamagnetism and Pauli spin paramagnetism have been exhibited upon using standard Skyrme force parametrizations. Both effects almost cancel. As a result, the Thomas-Fermi moments of inertia, which assume explicitly the rigid-body expression, turn out to represent a rather good approximation of the semiclassical results. Finally the validity of the Inglis formula is discussed in this context.
Equilibrium deformations of rotating nuclei in a self-consistent semiclassical approach
1994, Physics Letters B
We study here equilibrium deformations of rotating nuclei within a self-consistent semiclassical cranking approach using the SkM^∗ Skyrme effective interaction. The different axial rotational configurations, i.e. where the rotation axis is parallel or perpendicular to the symmetry axis, are studied as well as the Jacobi bifurcation into triaxial rotational equilibrium shapes. Finally the validity of the concept of a rotating liquid drop which has been widely used for the determination of average shapes of rotating nuclei is assessed by comparison with our microscopic results.
Semiclassical approaches to nuclear dynamics
2017, Physics of Atomic Nuclei
A semiclassical collective response of heated, asymmetric, and rotating nuclei
2014, Physics of Atomic Nuclei
On the fission of <sup>56</sup>Ni and <sup>48</sup>Cr rotating nuclei
1995, Journal of Physics G: Nuclear and Particle Physics

^☆: Work partially performed through funds granted by a french-algerian agreement between CNRS and DRS.

View full text

A semiclassical description of rapidly rotating nuclei☆

Abstract

Phys. Rep.

Nucl. Phys.

Ann. Phys.

Ann. Phys.

Nucl. Phys.

Sov. J. Nucl. Phys.

Yad. Flz.

Phys. Lett.

Nucl. Phys.

Sov. J. Part. Nucl.

Fiz. Elem. Chastits At. Yadra