Hyperfine-resolved laser excitation and detection of nuclear isomer in trapped 229Th3+ ions

Abstract

We present a comprehensive theoretical investigation of hyperfine-resolved excitation and detection of the low-energy isomeric state of 229Th in trapped 229Th3+ ions. Using a quantum master equation approach, we analyze the dependence of the isomeric population on laser linewidth, detuning, and irradiation time, showing that their proper matching is essential for efficient excitation. We further propose two nuclear-state detection schemes based on three hyperfine-resolved electronic fluorescence channels at 690, 984, and 1088 nm. Our analysis shows that the 690-nm and 984-nm scheme yields detectable photon rates on the order of 104~s-1 per ion for each wavelength, whereas the 1088-nm scheme achieves a higher rate on the order of 105~s-1 per ion. By quantifying the trade-off between irradiation time and scan-step size, we show that the nuclear transition can be located within one month for a 100-MHz uncertainty using currently available vacuum-ultraviolet laser technology. These results provide practical guidance for trapped-ion 229Th spectroscopy and the development of nuclear clocks.