Nature Communications (May 2025)

New proton emitter 188At implies an interaction unprecedented in heavy nuclei

  • Henna Kokkonen,
  • Kalle Auranen,
  • Pooja Siwach,
  • Paramasivan Arumugam,
  • Andrew D. Briscoe,
  • Sarah Eeckhaudt,
  • Lidia S. Ferreira,
  • Tuomas Grahn,
  • Paul T. Greenlees,
  • Pete Jones,
  • Rauno Julin,
  • Sakari Juutinen,
  • Matti Leino,
  • Ari-Pekka Leppänen,
  • Enrico Maglione,
  • Markus Nyman,
  • Robert D. Page,
  • Janne Pakarinen,
  • Panu Rahkila,
  • Jan Sarén,
  • Catherine Scholey,
  • Juha Sorri,
  • Juha Uusitalo,
  • Martin Venhart

DOI
https://doi.org/10.1038/s41467-025-60259-6
Journal volume & issue
Vol. 16, no. 1
pp. 1 – 6

Abstract

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Abstract We report the discovery of a new atomic nucleus 188At, which is the heaviest proton-emitting isotope known to date. The new activity was observed through the 107Ag(84Sr, 3n)188At fusion-evaporation reaction using the focal-plane spectrometer of the gas-filled recoil separator in the Accelerator Laboratory of the University of Jyväskylä, Finland. To fully interpret the experimental data, we have expanded the non-adiabatic quasiparticle model to treat nuclei in the beyond-lead region. The description reproduced the measured decay rate and pointed towards emission from an extremely prolate-deformed state with a dominant s 1/2 proton component in the wave function. The Thomas-Ehrman shift can be enhanced in low angular momentum states, but such effects have not been observed in heavy nuclei. The single-proton separation energy of 188At deviates from that extrapolated from the systematics, which can be interpreted as the first evidence of this effect in heavy nuclei.