Isomer Decay Spectroscopy of<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:mmultiscripts><mml:mrow><mml:mi>Sm</mml:mi></mml:mrow><mml:mprescripts /><mml:none /><mml:mrow><mml:mn>164</mml:mn></mml:mrow></mml:mmultiscripts></mml:mrow></mml:math>and<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:mmultiscripts><mml:mrow><mml:mi>Gd</mml:mi></mml:mrow><mml:mprescripts /><mml:none /><mml:mrow><mml:mn>166</mml:mn></mml:mrow></mml:mm

Patel, Z.; Söderström, P.-A.; Podolyák, Zs.; Regan, P. H.; Walker, P. M.; Watanabe, H.; Ideguchi, E.; Simpson, G. S.; Liu, H. L.; Nishimura, S.; Wu, Qiang; Xu, F. R.; Browne, F.; Doornenbal, P.; Lorusso, G.; Rice, S.; Sinclair, L.; Sumikama, T.; Wu, J.; Xu, Z. Y.; Aoi, N.; Baba, H.; Garrote, F. L. Bello; Benzoni, G.; Daido, R.; Fang, Y.; Fukuda, N.; Gey, G.; Go, S.; Gottardo, A.; Inabe, N.; Isobe, T.; Kameda, D.; Kobayashi, K.; Kobayashi, Masao; Komatsubara, T.; Kojouharov, I.; Kubo, T.; Kurz, N.; Kuti, I.; Li, Z.; Matsushita, M.; Michimasa, S.; Moon, Chang-Bum; Nıshıbata, H.; Nishizuka, I.; Odahara, A.; Şahin, E.; Sakuraï, H.; Schaffner, H.; Suzuki, Hiroshi; Takeda, Hiroyuki; Tanaka, M.; Taprogge, J.; Vajta, Zsolt; Yagi, A.; Yokoyama, R.

doi:10.1103/physrevlett.113.262502

Cited by 55 publications

(47 citation statements)

References 30 publications

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“…It is worth noting that important information relevant to the r-process has already been obtained from isomer spectroscopy, see for example Refs. [380,381,382]. With the development of the new rare-isotope beam facilities and improved experimental techniques, the discovery of neutron-decaying isomers [90] could also be within reach in the foreseeable future.…”

Section: Isomers and Nucleosynthesismentioning

confidence: 99%

Review of metastable states in heavy nuclei

2016

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Abstract.The structure of nuclear isomeric states is reviewed in the context of their role in contemporary nuclear physics research. Emphasis is given to high-spin isomers in heavy nuclei, with A 150. The possibility to exploit isomers to study some of the most exotic nuclei is a recurring theme. In spherical nuclei, the role of octupole collectivity is discussed in detail, while in deformed nuclei the limitations of the K quantum number are addressed. Isomer targets and isomer beams are considered, along with applications related to energy storage, astrophysics, medicine, and experimental advances.

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Section: Isomers and Nucleosynthesismentioning

confidence: 99%

Review of metastable states in heavy nuclei

2016

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“…The results with ε 6 = 0 are displayed to examine the high-order deformation effect. In general, compared to the ε 6 = 0 calculations, the non-zero ε 6 results reproduce the experimental multi-particle state energies better, except for the 1.486 MeV 6 − state in 164 Sm and the 1.350 MeV 4 + state in 166 Gd [11].…”

Section: Band Headmentioning

confidence: 66%

“…The nuclear structure inputs of the rare-earth nuclei can lead to an improved understanding of the r−process nucleosynthesis [3]. However, due to their neutron excess, detailed structure informations are very difficult to be revealed by the experiment in these rare-earth neutron-rich nuclei.The recent experimental progresses in the neutron-rich A = 150 − 170 region [4][5][6][7][8][9][10][11][12][13] are attributed to a great extent to the existence of the nuclear isomeric state. A nucleus can be "traped" in an aligned spin orientation relative to its symmetric axis to form the K isomeric state (or K-isomer), where K is a quantum number representing the projection of the total nuclear spin along the symmetry axis of the nucleus.…”

mentioning

confidence: 99%

“…Investigations of K-isomers have been reviewed recently in Refs. [14][15][16][17][18].An impressive progress has been achieved in experimental studies of samarium and gadolinium isotopes very recently [4,5,8,9,11,12]. The most exiting discoveries include: 160 Sm became the lightest nucleus with a known four-quasiparticle K-isomer [8], K-isomers were firstly observed in very neutron-rich nuclei 164 Sm and 166 Gd [11] and in odd-A samarium isotopes [4,5].…”

mentioning

confidence: 99%

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Insight into nuclear midshell structures by studying K isomers in rare-earth neutron-rich nuclei

He¹,

Li²

2018

Phys. Rev. C

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Inspired by the newly discovered isomeric states in the rare-earth neutron-rich nuclei, high-K isomeric states in neutron-rich samarium and gadolinium isotopes are investigated within the framework of the cranked shell model (CSM) with pairing correlation treated by a particle-numberconserving (PNC) method. The experimental multi-particle state energies and moments of inertia are reproduced quite well by the PNC-CSM calculations. A remarkable effect from the high-order deformation ε6 is demonstrated. Based on the occupation probabilities, the configurations are assigned to the observed high-K isomeric states. The lower 5 − isomeric state in 158 Sm is preferred as the two-proton state with configuration π 5 2 + [413]⊗π 5 2 − [532]. More low-lying two-particle states are predicted. The systematics of the electronic quadrupole transition probabilities, B(E2) values along the neodymium, samarium, gadolinium and dysprosium isotopes and N = 96, 98, 100, 102 isotones chains is investigated to reveal the midshell collectivities. * hext@nuaa.edu.cn arXiv:1808.03945v1 [nucl-th] 12 Aug 2018The rare-earth neutron-rich nuclei lie in the midshell region between the closed shells of proton Z = 50, 82 and neutron N = 82, 126. The high spin spectroscopy of these nuclei can provide important insights into the midshell collectivity, changes in nuclear shape and deformed sub-shells in a less-explored single-particle spectrum region. Furthermore, the pygmy rare-earth peak at A ∼ 160 of the r−process abundance is believed to arise from strong midshell nuclear deformation [1,2]. The nuclear structure inputs of the rare-earth nuclei can lead to an improved understanding of the r−process nucleosynthesis [3]. However, due to their neutron excess, detailed structure informations are very difficult to be revealed by the experiment in these rare-earth neutron-rich nuclei.The recent experimental progresses in the neutron-rich A = 150 − 170 region [4][5][6][7][8][9][10][11][12][13] are attributed to a great extent to the existence of the nuclear isomeric state. A nucleus can be "traped" in an aligned spin orientation relative to its symmetric axis to form the K isomeric state (or K-isomer), where K is a quantum number representing the projection of the total nuclear spin along the symmetry axis of the nucleus. K-isomer arises from the multi-particle state, of which the transition to a lower energy state with a different K value is inhibited by the ∆K ≤ λ selection rule where λ is the multipole order of the transition. However, symmetry-breaking processes make these transitions possible to process with the ∆K − λ related hindrance factor [14,15]. The multi-particle state is formed by breaking pairs of nucleon. The excitation energy and configuration of multi-particle state depend strongly on the position of the specific single-particle orbitals near the Fermi surface and correlations, such as pairing. K-isomer appears only in axially symmetric deformed nuclei well away from the closed shell. This implies that K-isomer cannot be a pure intrinsi...

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“…Recent theoretical calculation predicts a deformed shell closure at N = 100 [53]. This has also been experimentally verified recently [54] for Sm and Gd nuclei. This scenario may get changed if one moves towards the higher side of the rare-earth region.…”

mentioning

confidence: 67%

Systematic study of multi-quasiparticle K -isomeric bands in tungsten isotopes by the extended projected shell model

Ghorui

Wang

et al. 2017

Phys. Rev. C

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Background:The interplay between collective and single-particle degrees of freedom is an important structure aspect to study. The nuclei in the A ≈ 180 mass region are often denoted as good examples to study such problems because these nuclei are known to exhibit many rotational bands based on multi-quasiparticle K isomers. Purpose: A large set of high-quality experimental data on high-K isomeric states in the A ≈ 180 mass region has accumulated. A systematic description of them is a theoretical challenge as it requires a method going beyond the usual mean field with multi-quasiparticle configurations built in the shell-model basis. The K-isomer data provide an ideal testing ground for theoretical models. Method:The recently extended projected shell model (PSM) by the Pfaffian method is employed with a sufficiently large configuration space including up to 10 quasiparticles. The restoration of rotational symmetry which is broken in the deformed mean field is obtained by means of angular-momentum projection. With axial symmetry in the basis deformation, each multi-quasiparticle state, classified by a K quantum number, represents the major component of a rotational K band. Shell-model diagonalization in such a projected basis defines the K mixing, which is the key ingredient of the present method. Results: Quasiparticle structure and rotational properties of high-K isomers in even-even neutron-rich 174−186 W isotopes are described. The rotational evolution of the yrast and near-yrast bands is discussed with successive band crossings. Multi-quasiparticle K isomers and associated rotational bands in each W isotope are studied with detailed quasiparticle configurations given. Electromagnetic transition properties are also studied and the calculated B(E2), B(M1), and g-factors are compared with experiment if data exist. Conclusions: Many nuclei of the A ≈ 180 mass region exhibit properties of an axially symmetric shape and K is approximately a good quantum number. For such nuclei, the extended PSM assuming an axially symmetric basis but including K mixing through diagonalization of the two-body Hamiltonian is an appropriate method to study multi-quasiparticle K isomers and K violations in these states. For special examples where one finds highly K-forbidden transitions the present model needs to be further improved.

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Isomer Decay Spectroscopy ofSm164andGd166

Cited by 55 publications

References 30 publications

Review of metastable states in heavy nuclei

Review of metastable states in heavy nuclei

Insight into nuclear midshell structures by studying K isomers in rare-earth neutron-rich nuclei

Systematic study of multi-quasiparticle K -isomeric bands in tungsten isotopes by the extended projected shell model

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