English

Universal Effective Charges in the $sd$ and $fp$ Shells

Nuclear Experiment 2025-06-30 v1 Nuclear Theory

Abstract

The 247-keV state in 54^{54}Sc, populated in the β\beta decay of 54^{54}Ca, is reported here as a nanosecond isomer with a half-life of 26.0(22) ns. The state is interpreted as the 1+1^+ member of the πf7/2νf5/2\pi f_{7/2}\otimes\nu f_{5/2} spin-coupled multiplet, which decays to the 3+,πf7/2νp1/23^+,\pi f_{7/2} \otimes \nu p_{1/2} ground state. The new half-life corresponds to a pure E2E2 transition with a strength of 1.93(16) W.u., providing the most precise, unambiguous B(E2)B(E2) value in the neutron-rich fpfp region to date for a nucleus with valence protons above Z=20Z=20. Notably, it is roughly four times larger than the B(E2;1/25/2)B(E2; 1/2^{-} \rightarrow 5/2^{-}) value in 55^{55}Ca. The results, as compared to semi-empirical and ab initio shell-model calculations, indicate (1) a weak N=34N=34 sub-shell gap relative to N=32N = 32, (2) a large E2E2 enhancement in Sc as compared to Ca due to 1p1h1p-1h proton excitations across Z=28Z=28, and (3) empirical effective proton and neutron charges, eπe_\pi = 1.30(8)ee and eνe_\nu = 0.452(7)ee, respectively, that are in contrast to reports of eπ1.11.15ee_\pi \approx 1.1-1.15e and eν0.60.8ee_\nu \approx 0.6-0.8e for fpfp-shell nuclei near N=ZN = Z. We demonstrate that these reports are erroneous and that, in fact, a universal set of effective charges can be used across the sdsd and fpfp shells.

Keywords

Cite

@article{arxiv.2506.21852,
  title  = {Universal Effective Charges in the $sd$ and $fp$ Shells},
  author = {T. H. Ogunbeku and J. M. Allmond and T. J. Gray and W. -J. Ong and B. A. Brown and A. Gargano and R. Grzywacz and J. D. Holt and A. O. Macchiavelli and T. Miyagi and S. Neupane and B. C. Rasco and H. Schatz and B. M. Sherrill and O. B. Tarasov and H. Arora and A. D. Ayangeakaa and H. C. Berg and J. M. Berkman and D. L. Bleuel and K. Bosmpotinis and M. P. Carpenter and G. Cerizza and A. Chester and J. M. Christie and I. Cox and H. L. Crawford and B. P. Crider and J. Davis and A. A. Doetsch and J. G. Duarte and A. Estrade and A. Fijałkowska and C. Frantzis and T. Gaballah and E. C. Good and K. Haak and S. Hanai and J. T. Harke and A. C. Hartley and K. Hermansen and D. E. M. Hoff and D. Hoskins and J. Huffman and P. Van Isacker and R. Jain and M. Karny and T. T. King and N. Kitamura and K. Kolos and A. Laminack and S. N. Liddick and B. Longfellow and R. S. Lubna and S. Lyons and M. Madurga and M. J. Mogannam and G. Owens-Fryar and J R. Palomino and M. M. Rajabali and A. L. Richard and I. J. Richardson and E. K. Ronning and G. E. Rose and T. J. Ruland and K. P. Rykaczewski and N. D. Scielzo and D. P. Scriven and D. Seweryniak and K. Siegl and M. Singh and A. Spyrou and M. Stepaniuk and A. E. Stuchbery and A. Sweet and V. Tripathi and A. Tsantiri and S. Uthayakumaar and W. B. Walters and S. Watters and Z. Xu and R. Yokoyama},
  journal= {arXiv preprint arXiv:2506.21852},
  year   = {2025}
}

Comments

11 pages (including 1-page appendix), 5 figures, accepted by Physical Review Letters

R2 v1 2026-07-01T03:35:39.413Z