Frequency and Alignment Classification of Multiple Band Crossings

Riedinger, L. L.; Andersen, Ole; Frauendorf, S.; Garrett, J.D.; Gaardhøje, J. J.; Hagemann, G.B.; Herskind, B.; Makovetzky, Y.V.; Waddington, J. C.; Guttormsen, M.; Tjøm, P.O.

doi:10.1103/physrevlett.44.568

Cited by 132 publications

(39 citation statements)

References 9 publications

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“…Similar crossings are predicted for the 5/2 + [642] bands in the other oddmass, N=97 isotones, at comparable frequencies and with analogous properties; they should be searched for experimentally by extending the knowledge of these bands to higher spins. A similar phenomenon has recently been noticed in the experimental spectrum of 161yb [47]. These crossings with higher orbits in the vi13/2 and 7zh9/2 bands in this frequency range which is apparent in Fig.…”

Section: Comparison With Theoretical Calculationssupporting

confidence: 67%

Backbending in theN=96 isotones

Michel¹,

Vervier²

1981

Z Physik A

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The backbending in the even-even, N =96 isotones can be quantitatively accounted for by the rotation-alignment of the spins of neutrons in i 13/2 orbits, as shown by comparing the aligned angular momentum and relative Routhian for the s-bands in these isotones and for the i13/2 bands in the corresponding isotopes with N=97. The influence of protons on this backbending situation is shown to be indirect, acting through a change of the nuclear deformation, which yields a change of the moment of inertia of the g.s. band and of the non-rigid character of the rotation. The experimental data on the N =96 and 97 isotones are in reasonable agreement with cranking model calculations. Possible reasons for the inhibition of backbending in the h 9/2 proton bands in the odd-Z, N = 96 isotones, all related to a change of deformation, are presented.

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Section: Comparison With Theoretical Calculationssupporting

confidence: 67%

Backbending in theN=96 isotones

Michel¹,

Vervier²

1981

Z Physik A

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“…Similarly, the entropy S is also a function of T . In this section, we extract the exact level density from a simple theoretical model 3 . The Hamiltonian we use to obtain the eigenvalues and the level density ρ(E) is the simple pairing Hamiltonian…”

Section: Entropy From a Simple Pairing Modelmentioning

confidence: 99%

“…In high spin physics, the backbending phenomenon is a beautiful manifestation of the breaking of pairs. The mechanism is induced by Coriolis forces tending to align single particle angular momenta along the nuclear rotational axis [3,4]. Theoretical models also predict reduction in the pair correlations at higher temperatures [5][6][7].…”

Section: Introductionmentioning

confidence: 97%

Entropy in hot161,162Dyand171
Guttormsen
¹
,
Bjerve
²
,
Hjorth‐Jensen
³

et al. 2000
Phys. Rev. C
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38
6
40
0
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The density of accessible levels at low spin in the ( 3 He,αγ) reaction has been extracted for the 161,162 Dy and 171,172 Yb nuclei. The entropy of the even-odd and even-even nuclei has been deduced as a function of excitation energy, and found to reach a maximum of 15 kB before neutron evaporation. The entropy of one quasi-particle outside an even-even core is found to be 1.70 (15) kB. This quasi-particle picture of hot nuclei is well accounted for within a simple pairing model. The onset of two, four and six quasi-particle excitations in the 162 Dy and 172 Yb nuclei is discussed and compared to theory. The number of quasi-particles excited per excitation energy is a measure for the ratio of the level energy spacing and the pairing strength. PACS number(s): 21.10. Ma, 24.10.Pa, 25.55.Hp, 27.70.+q

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“…Though first nucleon alignments have been established and characterized in many deformed nuclei, the knowledge and understanding of subsequent alignments is limited, and discussions addressing the issue can be found for only a small number of nuclei, e.g., Refs. [15][16][17][18][19][20][21][22]. The characterization of nucleon alignments provides insight into the underlying configurations of rotational bands in addition to checking the validity of predictions of cranking calculations at high rotational frequencies.…”

Section: Introductionmentioning

confidence: 99%

Search for strongly deformed structures and observation of multiple nucleon alignments inW174

et al. 2008

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Highly excited states, up to spin 39h, have been established in 174 W, using the Gammasphere array. Ultimate cranker calculations predict the appearance of triaxial, strongly deformed structures above spin 30h in 174 W. A new approach was developed for a comprehensive search of the data for such structures, similar to those observed in the Lu and Hf isotopes. No evidence was found for strongly deformed bands in the W isotopes populated in this experiment. Existing rotational structures have been considerably extended, allowing for the observation of both neutron and proton alignments in a number of bands. There is evidence for the i 13/2 neutron and possibly both the h 9/2 and h 11/2 proton crossings. The observed neutron and proton crossing frequencies are in good agreement with predictions of Woods-Saxon cranking calculations using an empirical pair-gap energy, and they lead to an improved understanding of the underlying structure of the bands.

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Frequency and Alignment Classification of Multiple Band Crossings

Cited by 132 publications

References 9 publications

Backbending in theN=96 isotones

Backbending in theN=96 isotones

Entropy in hot161,162Dyand171
Guttormsen
¹
,
Bjerve
²
,
Hjorth‐Jensen
³

et al. 2000
Phys. Rev. C
Self Cite
38
6
40
0
View full text Add to dashboard Cite

Search for strongly deformed structures and observation of multiple nucleon alignments inW174

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Frequency and Alignment Classification of Multiple Band Crossings

Cited by 132 publications

References 9 publications

Backbending in theN=96 isotones

Backbending in theN=96 isotones

Entropy in hot161,162Dyand171Guttormsen1, Bjerve2, Hjorth‐Jensen3 et al. 2000Phys. Rev. CSelf Cite386400View full textAdd to dashboardCite

Search for strongly deformed structures and observation of multiple nucleon alignments inW174

Contact Info

Product

Resources

About

Entropy in hot161,162Dyand171
Guttormsen
¹
,
Bjerve
²
,
Hjorth‐Jensen
³

et al. 2000
Phys. Rev. C
Self Cite
38
6
40
0
View full text Add to dashboard Cite