Cargando…
The structure of low-lying states in ${}^{140}$Sm studied by Coulomb excitation
The electromagnetic structure of $^{140}$Sm was studied in a low-energy Coulomb excitation experiment with a radioactive ion beam from the REX-ISOLDE facility at CERN. The $2^+$ and $4^+$ states of the ground-state band and a second $2^+$ state were populated by multi-step excitation. The analysis o...
| Autores principales: | , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , |
|---|---|
| Lenguaje: | eng |
| Publicado: |
2016
|
| Materias: | |
| Acceso en línea: | https://dx.doi.org/10.1103/PhysRevC.93.054303 http://cds.cern.ch/record/2137039 |
| _version_ | 1780949993376448512 |
|---|---|
| author | Klintefjord, M. Hadyńska-Klȩk, K. Görgen, A. Bauer, C. Bello Garrote, F.L. Bönig, S. Bounthong, B. Damyanova, A. Delaroche, J.P. Fedosseev, V. Fink, D.A. Giacoppo, F. Girod, M. Hoff, P. Imai, N. Korten, W. Larsen, A.C. Libert, J. Lutter, R. Marsh, B.A. Molkanov, P.L. Naïdja, H. Napiorkowski, P. Nowacki, F. Pakarinen, J. Rapisarda, E. Reiter, P. Renstrøm, T. Rothe, S. Seliverstov, M.D. Siebeck, B. Siem, S. Srebrny, J. Stora, T. Thöle, P. Tornyi, T.G. Tveten, G.M. Van Duppen, P. Vermeulen, M.J. Voulot, D. Warr, N. Wenander, F. De Witte, H. Zielińska, M. |
| author_facet | Klintefjord, M. Hadyńska-Klȩk, K. Görgen, A. Bauer, C. Bello Garrote, F.L. Bönig, S. Bounthong, B. Damyanova, A. Delaroche, J.P. Fedosseev, V. Fink, D.A. Giacoppo, F. Girod, M. Hoff, P. Imai, N. Korten, W. Larsen, A.C. Libert, J. Lutter, R. Marsh, B.A. Molkanov, P.L. Naïdja, H. Napiorkowski, P. Nowacki, F. Pakarinen, J. Rapisarda, E. Reiter, P. Renstrøm, T. Rothe, S. Seliverstov, M.D. Siebeck, B. Siem, S. Srebrny, J. Stora, T. Thöle, P. Tornyi, T.G. Tveten, G.M. Van Duppen, P. Vermeulen, M.J. Voulot, D. Warr, N. Wenander, F. De Witte, H. Zielińska, M. |
| author_sort | Klintefjord, M. |
| collection | CERN |
| description | The electromagnetic structure of $^{140}$Sm was studied in a low-energy Coulomb excitation experiment with a radioactive ion beam from the REX-ISOLDE facility at CERN. The $2^+$ and $4^+$ states of the ground-state band and a second $2^+$ state were populated by multi-step excitation. The analysis of the differential Coulomb excitation cross sections yielded reduced transition probabilities between all observed states and the spectroscopic quadrupole moment for the $2_1^+$ state. The experimental results are compared to large-scale shell model calculations and beyond-mean-field calculations based on the Gogny D1S interaction with a five-dimensional collective Hamiltonian formalism. Simpler geometric and algebraic models are also employed to interpret the experimental data. The results indicate that $^{140}$Sm shows considerable $\gamma$ softness, but in contrast to earlier speculation no signs of shape coexistence at low excitation energy. This work sheds more light on the onset of deformation and collectivity in this mass region. |
| id | cern-2137039 |
| institution | Organización Europea para la Investigación Nuclear |
| language | eng |
| publishDate | 2016 |
| record_format | invenio |
| spelling | cern-21370392022-08-10T12:42:51Zdoi:10.1103/PhysRevC.93.054303http://cds.cern.ch/record/2137039engKlintefjord, M.Hadyńska-Klȩk, K.Görgen, A.Bauer, C.Bello Garrote, F.L.Bönig, S.Bounthong, B.Damyanova, A.Delaroche, J.P.Fedosseev, V.Fink, D.A.Giacoppo, F.Girod, M.Hoff, P.Imai, N.Korten, W.Larsen, A.C.Libert, J.Lutter, R.Marsh, B.A.Molkanov, P.L.Naïdja, H.Napiorkowski, P.Nowacki, F.Pakarinen, J.Rapisarda, E.Reiter, P.Renstrøm, T.Rothe, S.Seliverstov, M.D.Siebeck, B.Siem, S.Srebrny, J.Stora, T.Thöle, P.Tornyi, T.G.Tveten, G.M.Van Duppen, P.Vermeulen, M.J.Voulot, D.Warr, N.Wenander, F.De Witte, H.Zielińska, M.The structure of low-lying states in ${}^{140}$Sm studied by Coulomb excitationNuclear Physics - ExperimentThe electromagnetic structure of $^{140}$Sm was studied in a low-energy Coulomb excitation experiment with a radioactive ion beam from the REX-ISOLDE facility at CERN. The $2^+$ and $4^+$ states of the ground-state band and a second $2^+$ state were populated by multi-step excitation. The analysis of the differential Coulomb excitation cross sections yielded reduced transition probabilities between all observed states and the spectroscopic quadrupole moment for the $2_1^+$ state. The experimental results are compared to large-scale shell model calculations and beyond-mean-field calculations based on the Gogny D1S interaction with a five-dimensional collective Hamiltonian formalism. Simpler geometric and algebraic models are also employed to interpret the experimental data. The results indicate that $^{140}$Sm shows considerable $\gamma$ softness, but in contrast to earlier speculation no signs of shape coexistence at low excitation energy. This work sheds more light on the onset of deformation and collectivity in this mass region.The electromagnetic structure of Sm140 was studied in a low-energy Coulomb excitation experiment with a radioactive ion beam from the REX-ISOLDE facility at CERN. The 2+ and 4+ states of the ground-state band and a second 2+ state were populated by multistep excitation. The analysis of the differential Coulomb excitation cross sections yielded reduced transition probabilities between all observed states and the spectroscopic quadrupole moment for the 21+ state. The experimental results are compared to large-scale shell model calculations and beyond-mean-field calculations based on the Gogny D1S interaction with a five-dimensional collective Hamiltonian formalism. Simpler geometric and algebraic models are also employed to interpret the experimental data. The results indicate that Sm140 shows considerable γ softness, but in contrast to earlier speculation no signs of shape coexistence at low excitation energy. This work sheds more light on the onset of deformation and collectivity in this mass region.The electromagnetic structure of $^{140}$Sm was studied in a low-energy Coulomb excitation experiment with a radioactive ion beam from the REX-ISOLDE facility at CERN. The $2^+$ and $4^+$ states of the ground-state band and a second $2^+$ state were populated by arXiv:1603.01525oai:cds.cern.ch:21370392016-03-04 |
| spellingShingle | Nuclear Physics - Experiment Klintefjord, M. Hadyńska-Klȩk, K. Görgen, A. Bauer, C. Bello Garrote, F.L. Bönig, S. Bounthong, B. Damyanova, A. Delaroche, J.P. Fedosseev, V. Fink, D.A. Giacoppo, F. Girod, M. Hoff, P. Imai, N. Korten, W. Larsen, A.C. Libert, J. Lutter, R. Marsh, B.A. Molkanov, P.L. Naïdja, H. Napiorkowski, P. Nowacki, F. Pakarinen, J. Rapisarda, E. Reiter, P. Renstrøm, T. Rothe, S. Seliverstov, M.D. Siebeck, B. Siem, S. Srebrny, J. Stora, T. Thöle, P. Tornyi, T.G. Tveten, G.M. Van Duppen, P. Vermeulen, M.J. Voulot, D. Warr, N. Wenander, F. De Witte, H. Zielińska, M. The structure of low-lying states in ${}^{140}$Sm studied by Coulomb excitation |
| title | The structure of low-lying states in ${}^{140}$Sm studied by Coulomb excitation |
| title_full | The structure of low-lying states in ${}^{140}$Sm studied by Coulomb excitation |
| title_fullStr | The structure of low-lying states in ${}^{140}$Sm studied by Coulomb excitation |
| title_full_unstemmed | The structure of low-lying states in ${}^{140}$Sm studied by Coulomb excitation |
| title_short | The structure of low-lying states in ${}^{140}$Sm studied by Coulomb excitation |
| title_sort | structure of low-lying states in ${}^{140}$sm studied by coulomb excitation |
| topic | Nuclear Physics - Experiment |
| url | https://dx.doi.org/10.1103/PhysRevC.93.054303 http://cds.cern.ch/record/2137039 |
| work_keys_str_mv | AT klintefjordm thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT hadynskaklekk thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT gorgena thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT bauerc thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT bellogarrotefl thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT bonigs thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT bounthongb thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT damyanovaa thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT delarochejp thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT fedosseevv thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT finkda thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT giacoppof thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT girodm thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT hoffp thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT imain thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT kortenw thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT larsenac thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT libertj thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT lutterr thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT marshba thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT molkanovpl thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT naidjah thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT napiorkowskip thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT nowackif thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT pakarinenj thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT rapisardae thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT reiterp thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT renstrømt thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT rothes thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT seliverstovmd thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT siebeckb thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT siems thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT srebrnyj thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT storat thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT tholep thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT tornyitg thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT tvetengm thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT vanduppenp thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT vermeulenmj thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT voulotd thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT warrn thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT wenanderf thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT dewitteh thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT zielinskam thestructureoflowlyingstatesin140smstudiedbycoulombexcitation AT klintefjordm structureoflowlyingstatesin140smstudiedbycoulombexcitation AT hadynskaklekk structureoflowlyingstatesin140smstudiedbycoulombexcitation AT gorgena structureoflowlyingstatesin140smstudiedbycoulombexcitation AT bauerc structureoflowlyingstatesin140smstudiedbycoulombexcitation AT bellogarrotefl structureoflowlyingstatesin140smstudiedbycoulombexcitation AT bonigs structureoflowlyingstatesin140smstudiedbycoulombexcitation AT bounthongb structureoflowlyingstatesin140smstudiedbycoulombexcitation AT damyanovaa structureoflowlyingstatesin140smstudiedbycoulombexcitation AT delarochejp structureoflowlyingstatesin140smstudiedbycoulombexcitation AT fedosseevv structureoflowlyingstatesin140smstudiedbycoulombexcitation AT finkda structureoflowlyingstatesin140smstudiedbycoulombexcitation AT giacoppof structureoflowlyingstatesin140smstudiedbycoulombexcitation AT girodm structureoflowlyingstatesin140smstudiedbycoulombexcitation AT hoffp structureoflowlyingstatesin140smstudiedbycoulombexcitation AT imain structureoflowlyingstatesin140smstudiedbycoulombexcitation AT kortenw structureoflowlyingstatesin140smstudiedbycoulombexcitation AT larsenac structureoflowlyingstatesin140smstudiedbycoulombexcitation AT libertj structureoflowlyingstatesin140smstudiedbycoulombexcitation AT lutterr structureoflowlyingstatesin140smstudiedbycoulombexcitation AT marshba structureoflowlyingstatesin140smstudiedbycoulombexcitation AT molkanovpl structureoflowlyingstatesin140smstudiedbycoulombexcitation AT naidjah structureoflowlyingstatesin140smstudiedbycoulombexcitation AT napiorkowskip structureoflowlyingstatesin140smstudiedbycoulombexcitation AT nowackif structureoflowlyingstatesin140smstudiedbycoulombexcitation AT pakarinenj structureoflowlyingstatesin140smstudiedbycoulombexcitation AT rapisardae structureoflowlyingstatesin140smstudiedbycoulombexcitation AT reiterp structureoflowlyingstatesin140smstudiedbycoulombexcitation AT renstrømt structureoflowlyingstatesin140smstudiedbycoulombexcitation AT rothes structureoflowlyingstatesin140smstudiedbycoulombexcitation AT seliverstovmd structureoflowlyingstatesin140smstudiedbycoulombexcitation AT siebeckb structureoflowlyingstatesin140smstudiedbycoulombexcitation AT siems structureoflowlyingstatesin140smstudiedbycoulombexcitation AT srebrnyj structureoflowlyingstatesin140smstudiedbycoulombexcitation AT storat structureoflowlyingstatesin140smstudiedbycoulombexcitation AT tholep structureoflowlyingstatesin140smstudiedbycoulombexcitation AT tornyitg structureoflowlyingstatesin140smstudiedbycoulombexcitation AT tvetengm structureoflowlyingstatesin140smstudiedbycoulombexcitation AT vanduppenp structureoflowlyingstatesin140smstudiedbycoulombexcitation AT vermeulenmj structureoflowlyingstatesin140smstudiedbycoulombexcitation AT voulotd structureoflowlyingstatesin140smstudiedbycoulombexcitation AT warrn structureoflowlyingstatesin140smstudiedbycoulombexcitation AT wenanderf structureoflowlyingstatesin140smstudiedbycoulombexcitation AT dewitteh structureoflowlyingstatesin140smstudiedbycoulombexcitation AT zielinskam structureoflowlyingstatesin140smstudiedbycoulombexcitation |