Similarity of nuclear structure in the<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mmultiscripts><mml:mi mathvariant="normal">Sn</mml:mi><mml:mprescripts /><mml:none /><mml:mrow><mml:mn>132</mml:mn></mml:mrow></mml:mmultiscripts></mml:math>and<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mmultiscripts><mml:mi mathvariant="normal">Pb</mml:mi><mml:mprescripts /><mml:none /><mml:mrow><mml:mn>208</mml:mn></mml:mrow></mml:mmultiscripts></mml:mat

Coraggio, L.; Covello, A.; Gargano, A.; Itaco, N.

doi:10.1103/physrevc.80.021305

Cited by 57 publications

(37 citation statements)

References 27 publications

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“…Monopole energy shifts of single-particle levels have been observed in other mass region [33][34][35] and a similar problem related to an anomalous low-lying 5/2 + state in 135 Sb has been explained by recent shell-model calculations [36]. Similar calculations in the 208 Pb region have been initiated [37]. It will be interesting to compare our recent findings with these or other shell-model calculations.…”

supporting

confidence: 76%

β−decay of the neutron-rich isotope215Pb

et al. 2013

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This Brief Report reports on the first observation of the β − -delayed γ decay of 215 Pb, feeding states in 215 Bi. The 215 Pb beam was produced using resonant laser ionization and mass separated at the ISOLDE-CERN on-line mass separator. This ensured clean identification of the γ rays as belonging to the decay of 215 Pb or its β-decay daughters. A half-life of 147 (12) Despite the wealth of experimental data available for the doubly magic nucleus 208 Pb (Z = 82,N = 126) and its closest neighbors, the more neutron-rich lead isotopes remain poorly explored. The reason for the limited spectroscopic information lies in the experimental difficulties to access this region of the nuclear chart. Indeed the high N/Z ratio of these isotopes rules out heavy-ion fusion-evaporation reactions to produce the nuclei of interest and spallation reactions suffer from high contamination levels from more abundantly produced isobars.However for which data were collected during the same experimental campaign have been reported elsewhere.The β − decay of 215 Pb has been observed at ISOLDE in a high-energy proton induced spallation reaction. A 1.4 GeV pulsed proton beam bombarded a thick (50 g/cm 2 ) UC x target. The proton beam, with an intensity of 3.1 × 10 13 particles per pulse was delivered by the PS booster, during a 16.8 s long supercycle, made of 14 equidistant pulses, 1.2 μs long each. Out of these 14 pulses, seven were sent to the ISOLDE target. After diffusion out of the target, the spallation products were selectively ionized in the resonance ionization laser ion source [10,11]. The element-selective laser ionization of the lead isotopes in the hot niobium cavity (2100 • C, 3 mm diameter, 30 mm length) was achieved in three steps: after doubling of the fundamental frequency in a nonlinear BBO (β barium borate) crystal, a tunable pulsed dye laser delivered a photon beam with a wavelength λ = 283.305 nm to raise a valence electron out of the 6p 2 (1/2,1/2) 0 ground state to a first excited atomic state 6p7s(1/2,1/2) 1 . For the second step, the wavelength of the second dye laser was tuned to 600.186 nm, thus exciting the atoms to a 6p8p(1/2,3/2) 2 state. The copper-vapor lasers, pumping the dye lasers, simultaneously provided the necessary energy for the final ionizing step.Subsequently, the ions were extracted by a 60 kV extraction voltage and mass separated by the ISOLDE-GPS separator. After every proton impact, the beam-gate was closed for 100 ms reducing the isobaric contamination, lowering the amount of 067303-1 0556-2813/2013/87(6)/067303(5)

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supporting

confidence: 76%

β−decay of the neutron-rich isotope215Pb

et al. 2013

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“…[38][39][40][41][42][43][44]) and heavier nuclei around shell closures [40,45,46]. The key to these calculations is a proper description of the monopole channel of the effective interaction [47], which determines the bulk properties of the effective interaction and governs the evolution of the effective singleparticle energies (the mean field) as a function of valence neutron and proton numbers [41,48].…”

Section: Introductionmentioning

confidence: 99%

Monopole-optimized effective interaction for tin isotopes

2012

Phys. Rev. C

100

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We present a systematic configuration-interaction shell-model calculation on the structure of light tin isotopes with a global optimized effective interaction. The starting point of the calculation is the realistic CD-Bonn nucleon-nucleon potential. The unknown single-particle energies of the 1d 3/2 , 2s 1/2 , and 0h 11/2 orbitals and the T = 1 monopole interactions are determined by fitting to the binding energies of 157 low-lying yrast states in 102−132 Sn. We apply the Hamiltonian to analyze the origin of the spin inversion between 101 Sn and 103 Sn that was observed recently and to explore the possible contribution from interaction terms beyond the normal pairing.PHYSICAL REVIEW C 86, 044323 (2012) TABLE I. Numbers of two-body matrix elements j α j β |V |j δ j γ J T for different sets of J and T .

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“…It is now established that the dynamic effects of nucleon-nucleon interaction result in the evolution of shell structure and hence the new magic number sequence in drip-line region. Over the last few decades, there is an ongoing argument about the nature of the 54 Ca nucleus [1][2][3]. however, these studies could not reach a common conclusion about the magicity of the 54 Ca nucleus.…”

Section: Introductionmentioning

confidence: 98%

“…The origin of magic nucleon numbers (2,8,20,28, 50, 82 and 126) had been explained by the phenomenon of complete filing of nucleus shells. The nuclei having magic numbers of nucleons in comparison with neighboring isotopes and isotones have more spherical shape, more nucleon separation energy values, specific scheme of lowest energy levels -resonance liked behavior of the first 2 + state energies E(2 + 1 ), ratios E(4 + 1 )/E(2 + 1 ), quadrupole deformation parameters δ.…”

Section: Introductionmentioning

confidence: 99%

Structural Stability and Level Density of Hot Rotating Doubly Magic Isotopes of Calcium

Kumar

Preetha

Vinodini

et al. 2015

JNP

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the recently reported doubly-magic nuclei 52 Ca and 54 Ca are discussed in comparison with the other magic isotopes of Calcium. the temperature effect is included in this study and hence the statistical approach to obtain the particle emission and level density are discussed in the context of temperature effect. We predict an increase in neutron emission for 54 Ca due to the abrupt decrease in neutron separation energy around t=0.4MeV. Since the drop in the separation energy is closely associated with the structural changes in the rotating nuclei, relative increase in neutron emission probability around certain values of temperature may be construed as evidence for the shape transition. Such effects are not obtained for 40,48,52 Ca isotopes. hence this statistical study reveals the higher stability of magic nature of 52 Ca than 54 Ca, against temperature.

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Similarity of nuclear structure in theSn132andPb208

Cited by 57 publications

References 27 publications

β−decay of the neutron-rich isotope215Pb

β−decay of the neutron-rich isotope215Pb

Monopole-optimized effective interaction for tin isotopes

Structural Stability and Level Density of Hot Rotating Doubly Magic Isotopes of Calcium

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