High-fidelity control of a 13C nuclear spin coupled to a tin-vacancy center in diamond

Abstract

Nuclear spins near group-IV defects in diamond are promising candidates for quantum memories in quantum network applications. Here, we demonstrate high-fidelity control of a single 13C nuclear spin coupled to a tin-vacancy (SnV) center in diamond. We perform a combination of optical and microwave pumping to achieve initialization into a combined electro-nuclear spin state with a fidelity of 99.74(3)\,\%. Harnessing a superconducting waveguide for radio-frequency driving, we demonstrate precise nuclear spin control: Ramsey measurements reveal a coherence time of T2* = 1.5(1)\,milliseconds, and we use dynamical decoupling to extend it to 1.35(3)\,seconds. We perform randomized benchmarking, yielding a single-qubit gate fidelity of 99.92(1)\,\%. This demonstrates a coherent spin-photon system with promising properties for quantum network nodes.