Coherent Spin-Photon Interface of single PL6 Color Centers in Silicon Carbide

Abstract

The PL6 color center in silicon carbide has recently emerged as a promising platform for quantum information processing, yet its coherent spin--photon interface has remained largely unexplored. Here we present a comprehensive investigation of single PL6 centers, combining spectroscopy with theoretical analysis. The excited-state fine structure is fully resolved using group-theoretical modeling and strain-dependent measurements. Under resonant excitation, we achieve a spin initialization fidelity of 99.69 0.03\% and a readout contrast of 98.31 1.03\%. The spin--photon--entangled A2 transition exhibits narrow optical linewidths ( 180~MHz) and a polarization visibility of 82\%. Coherent optical driving enables Rabi frequencies up to 2.895~GHz, while dynamical decoupling extends the spin coherence time from 0.5~ms to 5.70~ms. Our results establish PL6 as a competitive solid-state spin--photon interface hosted in a commercially available semiconductor platform.