Your search keyword '"N=Z nuclei"' showing total 4 results

1. Low-, medium-, and high-spin states in the N=Z+1 nucleus 63Ga

Author

Rudolph, D., Ragnarsson, I., Clark, R. M., Andreoiu, C., Carpenter, M. P., Ekman, J., Fahlander, C., Kondev, F. G., Lauritsen, T., Sarantites, D. G., Seweryniak, D., and Svensson, C. E.

Subjects

N=Z nuclei, gamma-ray spectroscopy, Nuclear Theory, Subatomic Physics, Nuclear Experiment, nuclear structure and decays

Abstract

The fusion-evaporation reaction 28Si+40Ca at 122 MeV beam energy was used to populate excited states in the N=Z+1 nucleus 63Ga. With the combination of the Gammasphere spectrometer and the Microball CsI(Tl) charged-particle detector array, the level scheme of 63Ga was extended by more than a factor of two in terms of number of γ-ray transitions and excited states, excitation energy (Ex>30 MeV), and angular momentum (I>30 ℏ). Nine regular sequences of states were newly established in the high-spin part of the level scheme. The majority of these rotational band structures could be connected to the previously known part of the level scheme by high-energy γ-ray transitions in the energy range Eγ=4–6 MeV. Low-spin states were assessed by shell-model calculations. The high-spin rotational bands were interpreted and classified by means of cranked Nilsson-Strutinsky calculations.

Published

2021

2. Onset of high-spin rotational bands in the N=Z nucleus 62Ga

Author

Rudolph, D., Ragnarsson, I., Åberg, S., Andreoiu, C., Carpenter, M. P., Clark, R. M., Ekman, J., Fahlander, C., Janssens, R. V. F., Kondev, F G, Lauritsen, T, Sarantites, D. G., Seweryniak, D., and Svensson, C. E.

Subjects

N=Z nuclei, gamma-ray spectroscopy, Nuclear Theory, Subatomic Physics, Nuclear Experiment, nuclear structure and decays

Abstract

The fusion-evaporation reaction 28Si + 40Ca at 122 MeV beam energy was used to populate high-spin states in the odd-odd N = Z nucleus 62Ga. With the combination of the Gammasphere spectrometer and the Microball CsI(Tl) charged-particle detector array the decay scheme of 62Ga was extended beyond 10 MeV excitation energy. The onset of band structures was observed. These high-spin rotational states are interpreted and classified by means of cranked Nilsson-Strutinsky calculations.

Published

2020

3. Enhanced collectivity along the NÂ =Â Z line: Lifetime measurements in44Ti,48Cr, and52Fe

Author

Herbert Hess, K. O. Zell, P. Reiter, A. Blazhev, B. Birkenbach, A. Vogt, D. Schneiders, L. Coraggio, T. Steinbach, L. Lewandowski, J. Litzinger, Thomas Braunroth, A. Gargano, B. Fu, S. M. Lenzi, Alfred Dewald, D. Rosiak, C. Müller-Gatermann, K. Wolf, M. Seidlitz, R. Hirsch, M. Queiser, B. Siebeck, K. Arnswald, Nunzio Itaco, C. Fransen, Arnswald, K., Braunroth, T., Seidlitz, M., Coraggio, L., Reiter, P., Birkenbach, B., Blazhev, A., Dewald, A., Fransen, C., Fu, B., Gargano, A., Hess, H., Hirsch, R., Itaco, N., Lenzi, S. M., Lewandowski, L., Litzinger, J., Mã¼ller-gatermann, C., Queiser, M., Rosiak, D., Schneiders, D., Siebeck, B., Steinbach, T., Vogt, A., Wolf, K., Zell, K. O., and Müller-Gatermann, C.

Subjects

History, Nuclear and High Energy Physics, Lifetime measurement, Lifetime measurements, Nuclear Theory, B(E2) value, B(E2) values, N=Z nuclei, RDDS, 01 natural sciences, Education, Physics and Astronomy (all), symbols.namesake, Recoil, 0103 physical sciences, Nuclear Experiment, 010306 general physics, Physics, Isotope, 010308 nuclear & particles physics, Isotone, lcsh:QC1-999, Computer Science Applications, symbols, Atomic physics, Hamiltonian (quantum mechanics), lcsh:Physics

Abstract

Lifetimes of the 2 1 + states in 44Ti, 48,50Cr, and 52Fe were determined with high accuracy exploiting the recoil distance Doppler-shift method. The reduced E2 transition strengths of 44Ti and 52Fe differ considerably from previously known values. A systematic increase in collectivity is found for the N = Z nuclei compared to neighboring isotopes. The B ( E2 ) values along the Ti, Cr, and Fe isotopic chains are compared to shell-model calculations employing established interactions for the 0 f 1 p shell, as well as a novel effective shell-model Hamiltonian starting from a realistic nucleon–nucleon potential. The theoretical approaches underestimate the B ( E2 ) values for the lower-mass Ti isotopes. Strong indication is found for particle-hole cross-shell configurations, recently corroborated by similar results for the neighboring isotone 42Ca.

Published

2017

4. Shell gaps and pn pairing interaction in N=Z nuclei

Author

Yang Sun, Jing-ye Zhang, and Kazunari Kaneko

Subjects

Physics, Nuclear and High Energy Physics, N=Z nuclei, Nuclear Theory, Binding energy, SHELL model, Shell (structure), Nuclear shell model, FOS: Physical sciences, pn pairing, Nuclear Theory (nucl-th), Nuclear physics, Pairing, Physics::Atomic and Molecular Clusters, Woods–Saxon potential, Nuclear Experiment (nucl-ex), Atomic physics, Nucleon, Nuclear Experiment, Nuclear theory, Shell gap

Abstract

We analyze the observed shell gaps in N=Z nuclei determined from the binding energy differences. It is found that the shell gaps can be described by the combined contributions from the single-particle level spacing, the like-nucleon pairing, and the proton-neutron pairing interaction. This conclusion is consistent with that of Chasman in Phys. Rev. Lett. 99 (2007) 082501. For the double-closed shell N=Z nuclei, the single-particle level spacings calculated with Woods-Saxon potential are very close to those obtained by subtracting the nn pairing interaction from the observed shell gap. For the sub-closed or non-closed shell N=Z nuclei, the pn pairing interaction is shown to be important for the observed shell gaps., 9 pages, 5 figures