Deterministic Laser-Writing of Spin Defects in Nanophotonic Cavities

Aaron M Day; Jonathan R Dietz; Maddie Sutula; Matthew Yeh; Evelyn L Hu

Deterministic Laser-Writing of Spin Defects in Nanophotonic Cavities

ORAL

Abstract

Robust engineering and characterization of spin-defect coupling to nanophotonic cavities remains a challenge in developing scalable quantum network nodes. Here we demonstrate direct laser writing of cavity-integrated spin defects using a nanosecond-pulsed above-bandgap laser. Photonic crystal cavities in 4H-silicon carbide serve as a nanoscope monitoring silicon monovacancy (V_Si^-) defect formation within the 100 nm³ cavity mode volume. We observe spin resonance, cavity-integrated photoluminescence, and excited-state lifetimes consistent with conventional defect formation methods, without need for post-irradiation thermal annealing. We further find an exponential reduction in excited state lifetime at fluences approaching the cavity amorphization threshold, and show single-shot laser annealing of intrinsic background defects at V_Si^-formation sites.

March 7, 2023, 6:00 PM – March 7, 2023, 6:12 PM

Publication: Day, A. M., Dietz, J. R., Sutula, M., Yeh, M., & Hu, E. L. (2022). Deterministic Laser Writing of Spin Defects in Nanophotonic Cavities. arXiv preprint arXiv:2210.00177.

Presenters

Aaron M Day

Harvard University

Authors

Aaron M Day

Harvard University
Jonathan R Dietz

Harvard University
Maddie Sutula

Harvard University
Matthew Yeh

Harvard University
Evelyn L Hu

Harvard University