CERN Accelerating science

Article
Report number arXiv:2209.10276
Title Observation of the radiative decay of the ${}^{229}\mathrm{Th}$ nuclear clock isomer
Author(s) Kraemer, Sandro (Leuven U. ; LMU Munich (main)) ; Moens, Janni (Leuven U.) ; Athanasakis-Kaklamanakis, Michail (Leuven U. ; CERN) ; Bara, Silvia (Leuven U.) ; Beeks, Kjeld (Vienna, Tech. U., Atominst.) ; Chhetri, Premaditya (Leuven U.) ; Chrysalidis, Katerina (CERN) ; Claessens, Arno (Leuven U.) ; Cocolios, Thomas E. (Leuven U.) ; Correia, João G.M. (Lisbon U.) ; De Witte, Hilde (Leuven U.) ; Ferrer, Rafael (Leuven U.) ; Geldhof, Sarina (Leuven U.) ; Heinke, Reinhard (CERN) ; Hosseini, Niyusha (Vienna, Tech. U., Atominst.) ; Huyse, Mark (Leuven U.) ; Köster, Ulli (Laue-Langevin Inst.) ; Kudryavtsev, Yuri (Leuven U.) ; Laatiaoui, Mustapha (Mainz U. ; Helmholtz Inst., Mainz ; Darmstadt, GSI) ; Lica, Razvan (CERN ; Bucharest, IFIN-HH) ; Magchiels, Goele (Leuven U.) ; Manea, Vladimir (Leuven U.) ; Merckling, Clement (Leuven U.) ; Pereira, Lino M.C. (Leuven U.) ; Raeder, Sebastian (Helmholtz Inst., Mainz ; Darmstadt, GSI) ; Schumm, Thorsten (Vienna, Tech. U., Atominst.) ; Sels, Simon (Leuven U.) ; Thirolf, Peter G. (LMU Munich (main)) ; Tunhuma, Shandirai Malven (Leuven U.) ; Bergh, Paul Van Den (Leuven U.) ; Van Duppen, Piet (Leuven U.) ; Vantomme, André (Leuven U.) ; Verlinde, Matthias (Leuven U.) ; Villarreal, Renan (Leuven U.) ; Wahl, Ulrich (U. Lisbon (main))
Publication 2023-05-24
Imprint 2022-09-21
Number of pages 15
In: Nature 617 (2023) 706–710
DOI 10.1038/s41586-023-05894-z (publication)
Subject category nucl-ex ; Nuclear Physics - Experiment
Abstract The nucleus of the radioisotope thorium-229 (${}^{229}$Th) features an isomer with an exceptionally low excitation energy that enables direct laser manipulation of nuclear states. For this reason, it is a leading candidate for use in next-generation optical clocks. This nuclear clock will be a unique tool, amongst others, for tests of fundamental physics. While first indirect experimental evidence for the existence of such an extraordinary nuclear state is significantly older, the proof of existence has been delivered only recently by observing the isomer's electron conversion decay and its hyperfine structure in a laser spectroscopy study, revealing information on the isomer's excitation energy, nuclear spin and electromagnetic moments. Further studies reported the electron conversion lifetime and refined the isomer's energy. In spite of recent progress, the isomer's radiative decay, a key ingredient for the development of a nuclear clock, remained unobserved. In this Letter, we report the detection of the radiative decay of this low-energy isomer in thorium-229 (${}^{229\mathrm{m}}$Th). By performing vacuum-ultraviolet spectroscopy of ${}^{229\mathrm{m}}$Th incorporated into large-bandgap CaF${}_2$ and MgF${}_2$ crystals at the ISOLDE facility at CERN, the photon vacuum wavelength of the isomer's decay is measured as 148.71(42) nm, corresponding to an excitation energy of 8.338(24) eV. This value is in agreement with recent measurements, and decreases the uncertainty by a factor of seven. The half-life of ${}^{229\mathrm{m}}$Th embedded in MgF${}_2$ is determined to be 670(102) s. The observation of the radiative decay in a large-bandgap crystal has important consequences for the design of a future nuclear clock and the improved uncertainty of the energy eases the search for direct laser excitation of the atomic nucleus.
Copyright/License preprint: (License: CC BY-NC-ND 4.0)
publication: © 2023-2024 The authors (License: under exclusive licence to Springer Nature Limited)



Corresponding record in: Inspire


 Записът е създаден на 2022-10-11, последна промяна на 2024-05-08


Пълен текст:
Сваляне на пълен текст
PDF