Plasmonic Diamond Membranes for Ultrafast Silicon Vacancy Emission
Publication information:
Andrew Boyce, Hengming Li, Nathaniel Wilson, Deniz Acil, Amirhassan Shams-Ansari, Srivatsa Chakravarthi, Christian Pederson, Qixin Shen, Nicholas Yama, Kai-Mei Fu, Marko Lončar, and Maiken Mikkelsen. 2024. “Plasmonic Diamond Membranes for Ultrafast Silicon Vacancy Emission”. Nano Letters, 24, 12, Pp. 3575
Abstract
Silicon vacancy centers (SiVs) in diamond have emerged as a promising platform for quantum sciences due to their excellent photostability, minimal spectral diffusion, and substantial zero-phonon line emission. However, enhancing their slow nanosecond excited-state lifetime by coupling to optical cavities remains an outstanding challenge, as current demonstrations are limited to ∼10-fold. Here, we couple negatively charged SiVs to sub-diffraction-limited plasmonic cavities and achieve an instrument-limited ≤8 ps lifetime, corresponding to a 135-fold spontaneous emission rate enhancement and a 19-fold photoluminescence enhancement. Nanoparticles are printed on ultrathin diamond membranes on gold films which create arrays of plasmonic nanogap cavities with ultrasmall volumes. SiVs implanted at 5 and 10 nm depths are examined to elucidate surface effects on their lifetime and brightness. The interplay between cavity, implantation depth, and ultrathin diamond membranes provides insights into generating ultrafast, bright SiV emission for next-generation diamond devices.