Smooth trends in fermium charge radii and the impact of shell effects

Jessica Warbinek, Elisabeth Rickert, Sebastian Raeder, Thomas Albrecht-Schönzart, Brankica Andelic, Julian Auler, Benjamin Bally, Michael Bender, Sebastian Berndt, Michael Block, Alexandre Brizard, Pierre Chauveau, Bradley Cheal, Premaditya Chhetri, Arno Claessens, Antoine de Roubin, Charlie Devlin, Holger Dorrer, Christoph E. Düllmann, Julie EzoldRafael Ferrer, Vadim Gadelshin, Alyssa Gaiser, Francesca Giacoppo, Stephane Goriely, Manuel J. Gutiérrez, Ashley Harvey, Raphael Hasse, Reinhard Heinke, Fritz Peter Heßberger, Stephane Hilaire, Magdalena Kaja, Oliver Kaleja, Tom Kieck, Eun Kang Kim, Nina Kneip, Ulli Köster, Sandro Kraemer, Mustapha Laatiaoui, Jeremy Lantis, Nathalie Lecesne, Andrea Tzeitel Loria Basto, Andrew Kishor Mistry, Christoph Mokry, Iain Moore, Tobias Murböck, Danny Münzberg, Witold Nazarewicz, Thorben Niemeyer, Steven Nothhelfer, Sophie Péru, Andrea Raggio, Paul Gerhard Reinhard, Dennis Renisch, Emmanuel Rey-Herme, Jekabs Romans, Elisa Romero Romero, Jörg Runke, Wouter Ryssens, Hervé Savajols, Fabian Schneider, Joseph Sperling, Matou Stemmler, Dominik Studer, Petra Thörle-Pospiech, Norbert Trautmann, Mitzi Urquiza-González, Kenneth van Beek, Shelley Van Cleve, Piet Van Duppen, Marine Vandebrouck, Elise Verstraelen, Thomas Walther, Felix Weber, Klaus Wendt

Research output: Contribution to journalArticlepeer-review

Abstract

The quantum-mechanical nuclear-shell structure determines the stability and limits of the existence of the heaviest nuclides with large proton numbers Z ≳ 100 (refs. 1-3). Shell effects also affect the sizes and shapes of atomic nuclei, as shown by laser spectroscopy studies in lighter nuclides4. However, experimental information on the charge radii and the nuclear moments of the heavy actinide elements, which link the heaviest naturally abundant nuclides with artificially produced superheavy elements, is sparse5. Here we present laser spectroscopy measurements along the fermium (Z = 100) isotopic chain and an extension of data in the nobelium isotopic chain (Z = 102) across a key region. Multiple production schemes and different advanced techniques were applied to determine the isotope shifts in atomic transitions, from which changes in the nuclear mean-square charge radii were extracted. A range of nuclear models based on energy density functionals reproduce well the observed smooth evolution of the nuclear size. Both the remarkable consistency of model prediction and the similarity of predictions for different isotopes suggest a transition to a regime in which shell effects have a diminished effect on the size compared with lighter nuclei.

Original languageEnglish
Pages (from-to)1075-1079
Number of pages5
JournalNature
Volume634
Issue number8036
DOIs
StatePublished - Oct 1 2024

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