Spontaneous Raman scattering out of a metastable atomic qubit

Abstract

Metastable qubits in atomic systems can enable large-scale quantum computing by simplifying hardware requirements and adding efficient erasure conversion to the pre-existing toolbox of high-fidelity laser-based control. For trapped atomic ions, the fundamental error floor of this control is given by spontaneous Raman and Rayleigh scattering from short-lived excited states. We measure spontaneous Raman scattering rates out of a metastable D5/2 qubit manifold of a single trapped 40Ca+ ion illuminated by 976 nm light that is -44 THz detuned from the dipole-allowed transition to the P3/2 manifold. This supports the calculation of error rates from both types of scattering during one- and two-qubit gates on this platform, thus demonstrating that infidelities <10-4 are possible.