To reveal the chemical structure of single photon emission defects in hBN, different types of atoms (carbon, argon, germanium) were implanted into pure hBN flakes. More emission centers could be observed in carbon and germanium doped hBN than the argon doped hBN. It indicates the carbon and germanium related defects are more likely the emission centers in hBN. However, some emission defects can still be observed in hBN without any implantation. To find more conclusive evidence on the chemical structure of single photon emitters, hBN with less natural defects are required for the atom implantation, for instance, grown by metal organic vapor phase epitaxy or molecular beam epitaxy. To investigate the photophysics of defects by single molecule spectroscopy, I modified the existing confocal scanning photoluminescence microscope. Our results suggest there are at least two different types of defects with different phonon energies and at different positions of hBN. They can be selectively excited with different laser frequencies and both emit single photons.
We designed and fabricated plasmonic waveguides that can strongly enhance the emission rate and guide the emission direction of quantum emitters. Quantum emitters (molecules, ions) were coupled to the plasmonic waveguides, their optical properties, such as Raman scattering and flurescence have been characterised using the home-built microscope. We proposed a compact solid immersion metalens to collect the emission of single photon emitter with high collection efficiency. We developed an effective frequency domain technique to measure the lifetime of quantum emitters with high spectral resolution, in the regime of microseconds to milliseconds regime, which is hardly achieved by the existing techniques.
The result about the solid immersion metalens for directional single molecule emission has been submitted to peer-reviewed journal and is under review. One work about the broadband nano-de-focusing of plasmonically enhanced quantum emitter fluorescence is nearly ready to be submitted. Another paper about directional enhanced Raman scattering into plasmonic waveguide is in preparation and will be submitted soon. In addition, the paper about the novel effective frequency domain technique for spectrally resolved fluorescence lifetime measurement is currently in preparation.
We disseminated the results from this project to international conference. I gave an oral presentation about directional Raman scattering on International Conference of Nano-photonics and Nano-opteelectronics 2021. At London Plasmonic Forum 2021, my poster presentation on directional Raman scattering received the best poster award. I organised the first postdoc day of EXSS in Imperial in 2020 to invite the previous postdoc and Marie Curie fellows of Imperial to share their successful experience on scientific research and career development in academic and industry.