Suppression of differential light shifts in ground and metastable trapped-ion qubits

Abstract

In the presence of a magnetic field, hyperfine clock qubits can acquire a vector differential light shift that can be tuned via polarization to suppress the total differential light shift of high-power, off-resonant laser light. We experimentally measure this "magic" polarization condition, suppressing differential light shifts in both the 2S1/2 ground and 2F7/2o metastable clock qubits of 171Yb+. We present calculations of the minimum bias magnetic fields required to suppress differential light shifts in the ground state clock qubits of commonly trapped ion species, finding that they are below the strengths of fields already typically present in experiments. We further present methods for metastable clock-qubit control in 171Yb+, demonstrating a state preparation and measurement infidelity of 2.9+3.0-1.5×10-4 (-35 4 \, dB).