Finding the ultra-narrow 3\!P2 → \, 3\!P0 electric quadrupole transition in Ni12+ ion for an optical clock

Abstract

The Ni12+ ion features an electronic transition with a natural width of only 8 mHz, allowing for a highly stable optical clock. We predict that the energy of this strongly forbidden 3s2 3p4\, 3\!P2 → 3s2 3p4 \, 3\!P0 electric quadrupole transition is 20081(10) cm-1. For this, we use both a hybrid approach combining configuration interaction (CI) with coupled-cluster (CC) method and a pure CI calculation for the complete 16-electron system, ensuring convergence. The resulting very small theoretical uncertainty of only 0.05\% allowed us to find the transition experimentally in a few hours, yielding an energy of 20078.984(10) cm-1. This level of agreement for a 16-electron system is unprecedented and qualifies our method for future calculations of many other complex atomic systems. While paving the way for a high-precision optical clock based on Ni12+, our theory and code development will also enable better predictions for other highly charged ions and other complex atomic systems.

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