Towards Deterministic Creation of Single Photon Sources in Diamond using In-Situ Ion Counting (2112.02049v1)

Abstract: We present an in-situ counted ion implantation experiment reducing the error on the ion number to 5 % enabling the fabrication of high-yield single photon emitter devices in wide bandgap semiconductors for quantum applications. Typical focused ion beam implantation relies on knowing the beam current and setting a pulse length of the ion pulse to define the number of ions implanted at each location, referred to as timed implantation in this paper. This process is dominated by Poisson statistics resulting in large errors for low number of implanted ions. Instead, we use in-situ detection to measure the number of ions arriving at the substrate resulting in a two-fold reduction in the error on the number of implanted ions used to generate a single optically active silicon vacancy (SiV) defect in diamond compared to timed implantation. Additionally, through post-implantation analysis, we can further reduce the error resulting in a seven-fold improvement compared to timed implantation, allowing us to better estimate the conversion yield of implanted Si to SiV. We detect SiV emitters by photoluminescence spectroscopy, determine the number of emitters per location and calculate the yield to be 2.98 + 0.21 / - 0.24 %. Candidates for single photon emitters are investigated further by Hanbury-Brown-Twiss interferometry confirming that 82 % of the locations exhibit single photon emission statistics. This counted ion implantation technique paves the way towards deterministic creation of SiV when ion counting is used in combination with methods that improve the activation yield of SiV.