High-resolution spectroscopy and single-photon Rydberg excitation of reconfigurable ytterbium atom tweezer arrays utilizing a metastable state

Abstract

We present an experimental system for Rydberg tweezer arrays with ytterbium (Yb) atoms featuring internal state manipulation between the ground 1S0 and the metastable 3P2 states, and single-photon excitation from the 3P2 to Rydberg states. In the experiments, single Yb atoms are trapped in two-dimensional arrays of optical tweezers and are detected by fluorescence imaging with the intercombination 1S0 3P1 transition, and the defect-free single atom arrays are prepared by the rearrangement with the feedaback. We successfully perform high-resolution 1S0 3P2 state spectroscopy for the single atoms, demonstrating the utilities of this ultranarrow transition. We further perform single-photon excitation from the 3P2 to Rydberg states for the single atoms, which is a key for the efficient Rydberg excitation. We also perform a systematic measurement of a complex energy structure of a series of D states including newly observed 3D3 states. The developed system shows feasibility of future experiments towards quantum simulations and computations using single Yb atoms.