Direct measurement of three different deformations near the ground state in an atomic nucleus
Montes, P. A., Pakarinen, J., Papadakis, P., Herzberg, R.-D., Julin, R., Rodríguez, R., Briscoe, A. D., Illana, A., Ojala, J., Ruotsalainen, P., Uusikylä, E., Alayed, B., Alharbi, A., Alonso-Sañudo, O., Auranen, K., Bogdanoff, V., Chadderton, J., Esmaylzadeh, A., Fransen, C., . . . Zimba, G. L. (2025). Direct measurement of three different deformations near the ground state in an atomic nucleus. Communications Physics, 8, Article 8. https://doi.org/10.1038/s42005-024-01928-8
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Communications PhysicsAuthors
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2025Copyright
© The Author(s) 2025
Atomic nuclei serve as prime laboratories for investigations of complex quantum phenomena, where minor nucleon rearrangements cause significant structural changes. 190Pb is the heaviest known neutron-deficient Pb isotope that can exhibit three distinct shapes: prolate, oblate, and spherical, with nearly degenerate excitation energies. Here we report on the combined results from three state-of-the-art measurements to directly observe these deformations in190Pb. Contrary to earlier interpretations, we associate the collective yrast band as predominantly oblate, while the non-yrast band with higher collectivity follows characteristics of more deformed, predominantly prolate bands. Direct measurement of the E0(0+→01+)E0(0 2+ →0 1+ ) transition and γ-e−− coincidence relations allowed us to locate and firmly assign the 02+02+ state in the level scheme and to discover a spherical 23+2 3+ state at 1281(1) keV with B(E2;23+→01+)=1.2(3)B(E2;2 3+ →0 1+ )=1.2(3) W.u. These assignments are based purely on observed transition probabilities and monopole strength values, and do not rely on model calculations for their interpretation.
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Springer NatureISSN Search the Publication Forum
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https://converis.jyu.fi/converis/portal/detail/Publication/244938505
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European Commission; Research Council of FinlandFunding program(s)
Research infrastructures, HE; Academy Project, AoF; ERC Consolidator Grant; MSCA Innovative Training Networks (ITN)
The content of the publication reflects only the author’s view. The funder is not responsible for any use that may be made of the information it contains.
Additional information about funding
This project has received funding from the European Union’s Horizon Europe Research and Innovation programme under Grant Agreement No. 101057511. The authors also thank the GAMMAPOOL European Spectroscopy Resource for the loan of the detectors for the JUROGAM 3 array. Support from the Science and Technology Facilities Council (UK) Grants No. ST/P004598/1 and ST/V001027/1, and the German Research Foundation (Deutsche Forschungsgemeinschaft, DFG), Grant No. FR 3276/3-1 is acknowledged. We thank Karl-Oskar Zell for making the 108Pd target. A.I. acknowledges funding from the European Union’s Horizon 2020 research and innovation programme under the Marie Skodowska-Curie Grant Agreement No. 847635. O.A.S. acknowledges funding from the Spanish MCIN/AEI/10.13039/501100011033 under Grant PID2021-126998OB-I00. B.S.N.S. acknowledges the financial support of the UKRI STFC through Grants No. ST/T001739/1 and ST/P005101/1. A.R. acknowledges the Academy of Finland Project No. 339245. M.S. acknowledges the Academy of Finland Project No. 354968 and the European Union’s Horizon 2020 research and innovation programme under Grant Agreement No. 771036 (ERC CoG MAIDEN). A.R. and J.W. acknowledge the European Union’s Horizon 2020 research and innovation programme under Grant Agreement No. 861198-LISA-H2020-MSCA-ITN-2019. ...License
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