Scalable registration of single quantum emitters within solid immersion lenses through femtosecond laser writing

Optically active silicon-vacancy (V$_{Si}$) centers in silicon carbide (SiC) serve as qubits, interfacing spins via photons. This capability allows the encoding of photonic information within the spin state and facilitates on-demand readout, promising applications such as quantum memories. However, electron irradiation, a common technique for creating defects in SiC, lacks spatial selectivity, limiting scalability. We employed femtosecond laser writing within photonic structures to generate single (V$_{Si}$) centers, registering them to photonic structures and enhancing optical collection efficiency by a factor of 4.5. Characterization of 28 laser-written defects centers in solid immersion lenses (SILs) showed distributions relative to the photonic structure's center of 260 nm in the x-direction and 60 nm in the y-direction, with standard deviations of $\pm 170$ nm and $\pm 90$ nm, respectively. This method is scalable for developing integrated quantum devices using spin-photon interfaces in SiC.