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Q: Fachverband Quantenoptik und Photonik

Q 11: Precision Measurements I (joint session Q/A)

Q 11.3: Talk

Monday, March 11, 2024, 17:30–17:45, HS 1221

Electronic Bridge schemes in ²²⁹Th doped LiCAF — •Tobias Kirschbaum¹, Martin Pimon², and Adriana Pálffy¹ — ¹Julius-Maximilians-Universität Würzburg, Germany — ²Technische Universität Wien, Austria

Large band gap crystals such as CaF₂ or LiCaAlF₆ (LiCAF) are an ideal inert host for the nuclear clock candidate ²²⁹Th. Among others, these crystals are transparent with respect to the clock transition at ≈ 8 eV and a large number of nuclei can be interrogated at the same time [1]. However, DFT calculations indicate that doping of ²²⁹Th in these crystals leads to the formation of localized electronic states in the band gap, so-called defect states [2]. Due to their vicinity to the nuclear transition energy, these can be used for effective nuclear excitation via the Electronic Bridge mechanism, as we could show for the case of Th-doped CaF₂ crystals [2,3].

Here, we investigate theoretically different driven Electronic Bridge schemes for ²²⁹Th doped LiCAF crystals and present the corresponding excitation rates. These schemes enable a more efficient nuclear excitation/deexcitation compared to direct photoexcitation. The results are discussed in conjuncture with the design of a solid-state nuclear clock.

[1] G. A. Kazakov et al., New J. Phys. 14, 083019 (2012).

[2] B. S. Nickerson et al., Phys. Rev. Lett 125, 032501 (2020).

[3] B. S. Nickerson et al., Phys. Rev. A 103, 053120 (2021).

Keywords: Nuclear clock; VUV transparent crystals; Electromagnetic transitions