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A spinless crystal for a high-performance solid-state $^{229}$Th nuclear clock

Materials Science 2025-03-18 v1 Nuclear Theory Atomic Physics Optics

Abstract

Solid-state 229^{229}Th nuclear clocks require a host material whose band gap is larger than the 8.4 eV nuclear transition energy. As such, excitation of the 229^{229}Th nuclear state has so far only been demonstrated in metal fluorides, specifically CaF2_2, LiSrAlF6_6, and ThF4_4, where the large electronegativity of the halogen leads to sufficient band gaps. However, it is expected that the nuclear magnetic moment of the fluorine gives rise to a leading order broadening mechanism that limits the clock stability. Here, we use concepts of molecular design to identify a polyatomic anion, SO42_4^{2-}, that is both nuclear spin free and of sufficient electron affinity to result in a high band gap metal sulfate system. Using state-of-the-art calculations, we find that the band gap of Th(SO4_4)2_2 is approximately 9 eV, large enough for direct laser excitation of 229^{229}Th. Low concentrations of 229^{229}Th in the otherwise spinless 232^{232}Th(SO4_4)2_2 crystal mitigate 229^{229}Th-229^{229}Th interactions. Furthermore, the introduction of 229^{229}Th does not modify the material band gap nor introduce electronic states associated with nuclear quenching. By removing one of the primary sources of nuclear line broadening in the crystal, the nuclear magnetic dipole-dipole interaction, a nuclear clock with instability as low as σ=4.6×1023/τ\sigma = 4.6\times10^{-23}/\sqrt{\tau}, where τ{\tau} is the averaging time, may be realized. This is roughly six orders of magnitude lower than previously thought possible.

Cite

@article{arxiv.2503.11374,
  title  = {A spinless crystal for a high-performance solid-state $^{229}$Th nuclear clock},
  author = {Harry W. T. Morgan and James E. S. Terhune and Ricky Elwell and Hoang Bao Tran Tan and Udeshika C. Perera and Andrei Derevianko and Eric R. Hudson and Anastassia N. Alexandrova},
  journal= {arXiv preprint arXiv:2503.11374},
  year   = {2025}
}

Comments

7 pages of main text and references, 3 pages of supporting information. 2 figures

R2 v1 2026-06-28T22:20:35.352Z