New effective interaction for<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:mi>p</mml:mi><mml:mi>f</mml:mi></mml:mrow></mml:math>-shell nuclei and its implications for the stability of the<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:mi>N</mml:mi><mml:mo>=</mml:mo><mml:mi>Z</mml:mi><mml:mo>=</mml:mo><mml:mn>28</mml:mn></mml:mrow></mml:math>closed core

Honma, Mareki; Otsuka, Takaharu; Brown, B. A.; Mizusaki, T.

doi:10.1103/physrevc.69.034335

Cited by 549 publications

(622 citation statements)

References 69 publications

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“…First two columns show old and new experimental data, see [6] for details. Next three columns collect the results of shell-model calculations using MSDI3 [13], GXPF1 [14], and GXPF1A [15] interactions, respectively. Last column shows the results obtained in this work using six reference Slater determinants described in the text.…”

Section: No-core Configuration-interaction Calculations For 0 + Statementioning

confidence: 99%

Beta-Decay Studies in N ≈ Z Nuclei Using No-Core Configuration-Interaction Model

Satuła

Dobaczewski

Konieczka

2015

Proceedings of the Conference on Advances in Radioactive Isotope Science (ARIS2014)

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The no-core configuration-interaction model based on the isospin-and angular-momentum projected density functional formalism is introduced. Two applications of the model are presented: (i) determination of spectra of 0 + states in 62 Zn and (ii) determination of isospin-symmetry-breaking corrections to superallowed β-decay between isobaric-analogue 0 + states in 38 Ca and 38 K. It is shown that, without readjusting a single parameter of the underlying Skyrme interaction, in all three nuclei, the model reproduces the 0 + spectra surprisingly well.

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Section: No-core Configuration-interaction Calculations For 0 + Statementioning

confidence: 99%

Beta-Decay Studies in N ≈ Z Nuclei Using No-Core Configuration-Interaction Model

Satuła

Dobaczewski

Konieczka

2015

Proceedings of the Conference on Advances in Radioactive Isotope Science (ARIS2014)

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“…However, it has been shown that this core is rather soft and only a very limited description is provided by the closed-shell model for the magic number 28 [4]. These structures were successfully described for N or Z = 28 nuclei only after considering the existence of significant core-excitations in low-lying non-yrast states as well as in high-spin yrast states [3].…”

Section: Introductionmentioning

confidence: 99%

“…We have used the model space and the residual interaction named GXPF1, developed for the description of fp-nuclei [3,18]. The calculation with the GXPF1 interaction was performed in the full fp shell with up to eight particle excitations from the 1f 7/2 orbital to the 1p 3/2 , 1f 5/2 and 1p 1/2 orbitals.…”

Section: Shell Model Calculationsmentioning

confidence: 99%

“…Nuclei close to doubly magic shell closures have been the object of extensive experimental and theoretical investigations [1][2][3]. Spectroscopic data from these nuclei provide essential information for the parameter sets of spherical shell model calculations and apply severe constraints on the outcome of such calculations and, consequently, define the effective nuclear forces.…”

Section: Introductionmentioning

confidence: 99%

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Nuclear structure of the odd–odd nucleus⁵⁸Co

Silveira

Medina

Alcántara-Núñez

et al. 2005

J. Phys. G: Nucl. Part. Phys.

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The odd-odd 58 Co nucleus has been studied with the 51 V( 10 B, p2n) reaction at 33 MeV and 36 MeV incident energy using the γ -spectrometer Saci-Pererê. Excited states up to 8.0 MeV and spin up to 11 + have been observed. DSAM lifetimes for 13 excited states were measured. The results are compared to shell model calculations using the GXPF1 effective interaction, developed for use in the fp shell.

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“…The results are compared to Shell Model calculations using the GXPF1 effective interaction, developed for use in the fp shell. The πf −1 7/2 ⊗ν(p 2 3/2 f 1 5/2 ) configuration was assigned to the yrast levels.Nuclei close to doubly magic shell closures are the object of extensive experimental and theoretical investigations [1][2][3]. Spectroscopic data from these nuclei provide essential information for the parameter sets of spherical shell-model calculations.…”

mentioning

confidence: 99%

In-beam gamma ray spectroscopy of 58Co

et al. 2005

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The odd-odd 58 Co nucleus has been studied with the 51 V( 10 B, p2n) reaction at 33-MeV incident energy and the γ-spectrometer Saci-Pererê. Excited states up to 8.0 MeV and spin up to 11 + have been observed. The results are compared to Shell Model calculations using the GXPF1 effective interaction, developed for use in the fp shell. The πf −1 7/2 ⊗ν(p 2 3/2 f 1 5/2 ) configuration was assigned to the yrast levels.Nuclei close to doubly magic shell closures are the object of extensive experimental and theoretical investigations [1][2][3]. Spectroscopic data from these nuclei provide essential information for the parameter sets of spherical shell-model calculations. They apply severe constraints on the outcome of such calculations and, consequently, define the effective nuclear forces. During recent years both experimental and theoretical efforts have been used to understand the nuclei near the Z=N=28 shell closure. There is an N or Z=28 "magic" number inside the major shell with the oscillator quantum number N=3. The shell gap at N=Z=28 is due to the spin-orbit lowering of the f 7/2 orbital. This gap is relatively small so that the particle-hole excitation across the gap has relatively low energies. For shell model calculations around this magic number, 56 Ni has often been assumed as an inert core. However, it has been shown that this core is rather soft and only a very limited description is provided by the closed-shell model for the magic number 28 [4]. These structures were successfully described for N or Z = 28 nuclei only after considering the existence of significant core-excitations in low-lying non yrast states as well as in high-spin yrast states [3]. These calculations were performed for the 53 Mn, 54 Fe, 55 Co and 56,57,58,59 Ni nuclei.In this study we present new results on excited states of 58 Co, thus enriching the systematics of the nuclear structure along the N=31 chain. This nucleus has three particles and one hole relative to the 56 Ni core and has been studied so far with proton and α particle induced reactions [6-8], therefore very little was known regarding its high-spin structure.The 58 Co nuclei were produced with the fusion-evaporation reaction 51 V( 10 B,p2n) at 33 MeV bombarding energy, with the 8MV Pelletron accelerator of the University of São Paulo (USP). The target consisted of a stack of 3 self-supporting natural 51 V foils of 200 µg/cm 2 . Gamma-gamma-charged particle coincidences were measured with the Saci-Pererê γ-ray spectrometer. Saci [9] (Sistema Ancilar de Cintiladores) is a 4 π-charged particle system consisting of 11 plastic phoswich scintillator E-E telescopes. Pererê Gamma-ray spectrum from the 10 B on 51 V (E=33MeV) gated on the 321keV low-lying transition of the 58 Co nucleus, and on protons detected by the SACI array. These gamma-rays were assigned to the 58 Co nucleus.Canberra REGe of 60% efficiency). Two of these detectors were placed at 37 o and the other two at 101 o with respect to the beam direction. Events were collected when at least two HPGe detectors fi...

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New effective interaction forpf-shell nuclei and its implications for the stability of theN=Z=28closed core

Cited by 549 publications

References 69 publications

Beta-Decay Studies in N ≈ Z Nuclei Using No-Core Configuration-Interaction Model

Beta-Decay Studies in N ≈ Z Nuclei Using No-Core Configuration-Interaction Model

Nuclear structure of the odd–odd nucleus⁵⁸Co

In-beam gamma ray spectroscopy of 58Co

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New effective interaction forpf-shell nuclei and its implications for the stability of theN=Z=28closed core

Cited by 549 publications

References 69 publications

Beta-Decay Studies in N ≈ Z Nuclei Using No-Core Configuration-Interaction Model

Beta-Decay Studies in N ≈ Z Nuclei Using No-Core Configuration-Interaction Model

Nuclear structure of the odd–odd nucleus58Co

In-beam gamma ray spectroscopy of 58Co

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Nuclear structure of the odd–odd nucleus⁵⁸Co