Theoretical calculations find transition sensitivities K=9.40 in Y+ and K=9.73 in Ac+ to variation of α, enabling two-photon searches and detection schemes.
Yttrium ion as a platform for quantum information processing
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abstract
Engineering large-scale quantum computers which simultaneously provide high-fidelity quantum operations, low memory errors, low crosstalk, and reasonable resource usage remains an outstanding challenge across quantum computing platforms. In trapped ions, progress has largely focused on alkaline-earth and ytterbium ions, whose simple electronic structures facilitate control over their internal state. Here we investigate singly-ionized yttrium ($^{89}\mathrm{Y}^+$), a two-valence-electron ion whose ground-state manifold hosts a nuclear-spin qubit and which also features a variety of low-lying metastable manifolds, for applications in quantum information processing. Because experimental data are limited, we perform high-resolution laser-induced fluorescence spectroscopy to measure the hyperfine structure of several low-lying levels, and carry out comprehensive electronic structure calculations to determine lifetimes, transition matrix elements, and hyperfine coefficients for manifolds addressable with visible, near-visible, or infrared wavelengths. Using these results, we analyze schemes for qubit storage, initialization, readout, leakage mitigation, and single- and two-qubit gates. These results position $^{89}\mathrm{Y}^+$ as a uniquely capable next-generation trapped-ion qubit, combining field-insensitive nuclear-spin or clock-qubit storage with spectrally isolated transitions for operations.
fields
physics.atom-ph 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
citing papers explorer
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Low-lying $D$ states in yttrium and actinium ions highly sensitive to variation of the fine structure constant
Theoretical calculations find transition sensitivities K=9.40 in Y+ and K=9.73 in Ac+ to variation of α, enabling two-photon searches and detection schemes.