Excited-state magnetic properties of carbon-like Ca14+
Abstract
We measured the g-factor of the excited state 3P1 in Ca14+ ion to be g = 1.499032(6) with a relative uncertainty of 4×10-6. The magnetic field magnitude is derived from the Zeeman splitting of a Be+ ion, co-trapped in the same linear Paul trap as the highly charged Ca14+ ion. Furthermore, we experimentally determined the second-order Zeeman coefficient C2 of the 3P0 - 3P1 clock transition. For the mJ=0→ mJ'=0 transition, we obtain C2 = 0.390.04HzmT-2, which is to our knowledge the smallest reported for any atomic transition to date. This confirms the predicted low sensitivity of highly charged ions to higher-order Zeeman effects, making them ideal candidates for high-precision optical clocks. Comparison of the experimental results with our state-of-the art electronic structure calculations shows good agreement, and demonstrates the significance of the frequency-dependent Breit contribution, negative energy states and QED effects on magnetic moments.
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