216 research outputs found
Wobbling excitations at high spins in A~160
We found that in 156Dy and 162Yb the lowest odd spin gamma-vibrational states
transform to the wobbling excitations after the backbending, associated with
the transition from axially-symmetric to nonaxial shapes. The analysis of
quadrupole electric transitions determines uniquely the sign of the
gamma-deformation in both nuclei after the transition point.Comment: 6 pages, 4 figure
Electromagnetic Modes in Deformed Nuclei
A strength function method is adopted to describe a coupling between electric
and magnetic modes of different multipolarity. The collective vibrations are
analysed for a separable residual interaction in the framework of the
random-phase approximation. The coupling between and giant resonances
is considered as an illustrative example.Comment: 7 pages (latex), 1 figure (ps file), an invited talk at the workshop
"Symmetries and Spin - Praha 98", to be published in Czech.J.Phys., 199
Self-Consistent Separable RPA For Density- and Current-Dependent Forces
Self-consistent factorization of two-body residual interaction is proposed
for arbitrary density- and current-dependent energy functionals. Following this
procedure, a separable RPA (SRPA) method is constructed. SRPA dramatically
simplifies the calculations and demonstrates quick convergence to exact
results. The method is tested for SkM* forces.Comment: 10 pages, 1 figure, contribution to Proceedings of 7th International
Spring Seminar on Nuclear Physics, Maiori, Italy, May 27-31, 200
Individual low-energy E1 toroidal and compression states in light nuclei: deformation effect, spectroscopy and interpretation
The existence of individual low-energy E1 toroidal and compression states (TS
and CS) in Mg was predicted recently in the framework of quasiparticle
random-phase-approximation (QRPA) model with Skyrme forces. It was shown that
the strong axial deformation of Mg is crucial to downshift the toroidal
strength to the low-energy region and thus make the TS the lowest E1(K=1)
dipole state. In this study, we explain this result by simple mean-field
arguments. Comparing TS in two strongly axial nuclei, Mg and Ne,
we show that the lowest TS is not not a universal phenomenon but rather a
peculiarity of Mg. The spectroscopy of TS and CS is analyzed and some
additional interpretation of these states is suggested.Comment: 6 pages, 8 figures, 2 tables. Submitted to proceedings of
International Conference on Nuclear Structure and Related Topics - NSRT18
(Bulgaria, Bourgas, June 3-9, 2018). The paper was resubmitted to enlarge the
reference lis
Microscopic analysis of shape-phase transitions in even-even N~90 rotating nuclei
We study in cranked Nilsson plus random phase approximation shape transitions
in fast rotating nuclei undergoing backbending, more specifically 156Dy and
162Yb. We found that a backbending in 156Dy is correlated with the
disappearance of the collective, positive signature gamma-vibrational mode in
the rotating frame, and, a shape transition (from axial to nonaxial) is
accompanied with a large acquiring of the gamma-deformation. We show that such
a shape transition can be considered as a phase transition of the first order.
In 162Yb the quasiparticle alignment dominates in the backbending and the shape
transition (from axial to nonaxial) is accompanied with a smooth transition
from zero to nonzero values of the gamma-deformation. We extend the classical
Landau theory for rotating nuclei and show that the backbending in 162Yb is
identified with the second order phase transition. A description of spectral
and decay properties of the yrast states and low-lying excitations demonstrates
a good agreement between our results and experimental data.Comment: 22 pages, 13 figures, 2 table
Systematics of toroidal dipole modes in Ca, Ni, Zr, and Sn isotopes
We analyze the relation between isoscalar toroidal modes and so-called pygmy
dipole resonance (PDR) which both appear in the same region of low-energy
dipole excitations. To this end, we use a theoretical description within the
fully self-consistent Skyrme quasiparticle random-phase approximation (QRPA).
Test cases are spherical nuclei Ca, Ni, Zr, and
Sn which cover four different elements and for each element at
least two isotopes with different neutron excess, one small and another large.
The structure of the modes is investigated in terms of strength functions,
transition densities (TD) and transition currents (TC). For all considered
nuclei, we see that, independently on whether PDR strength exists or not, the
flow pattern in the lower part of the "PDR energy region" is basically the
isoscalar vortical toroidal motion with a minor irrotational fraction. A
one-to-one correspondence between calculated TD and TC can be established. The
toroidal flow appears already in the uncoupled two-quasiparticle (2qp)
excitations and becomes definitively strong for the QRPA modes. Altogether, we
find that low-lying dipole strength often denoted as isoscalar PDR is actually
an oversimplified imitation of the basically toroidal motion in nuclei with a
sufficient neutron excess.Comment: 12 pages, 14 figure
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