Laser spectroscopic characterization of the nuclear-clock isomer $^{229m}$Th

A Bohr; A Vascon; A Yamaguchi; AC Hayes; AM Dykhne; B Seiferle; Benedict Seiferle; BR Beck; CE Bemis; Christoph E. Düllmann; CJ Campbell; CJ Campbell; David M. Meier; DG Burke; DJ McCarron; E Litvinova; E Peik; E Peik; E Ruchowska; Ekkehard Peik; EV Tkalya; EV Tkalya; EV Tkalya; FF Karpeshin; GA Kazakov; H Kopfermann; II Sobelman; J Jeet; JC Berengut; JE Bjorkholm; Johannes Thielking; K Gulda; L Wense von der; L Wense von der; LA Kroger; Lars von der Wense; Maxim V. Okhapkin; MS Safronova; N Minkov; OA Herrera-Sancho; OA Herrera-Sancho; Peter G. Thirolf; Przemysław Głowacki; RG Helmer; RR Chasman; S Büttgenbach; S Gerstenkorn; S Matinyan; SG Nilsson; TG Wright; V Barci; VV Flambaum; W Kälber; WG Rellergert; WH King

Laser spectroscopic characterization of the nuclear-clock isomer $^{229m}$ Th

Abstract

The isotope

^{229}

Th is the only nucleus known to possess an excited state

^{229m}

Th in the energy range of a few electron volts, a transition energy typical for electrons in the valence shell of atoms, but about four orders of magnitude lower than common nuclear excitation energies. A number of applications of this unique nuclear system, which is accessible by optical methods, have been proposed. Most promising among them appears a highly precise nuclear clock that outperforms existing atomic timekeepers. Here we present the laser spectroscopic investigation of the hyperfine structure of

^{229m}

Th

^{2+}

, yielding values of fundamental nuclear properties, namely the magnetic dipole and electric quadrupole moments as well as the nuclear charge radius. After the recent direct detection of this long-searched-for isomer, our results now provide detailed insight into its nuclear structure and present a method for its non-destructive optical detection.Comment: 18 page