Androvitsaneas P.; Clark R.N.; Jordan M.; Alvarez Perez M.; Peach T.; Thomas S.; Shabbir S.; Sobiesierski A.D.; Trapalis A.; Farrer I.A.; Langbein W.W.; Bennett A.J. - Article - 123, 9, 94001, , , - 2023 - Applied Physics Letters
We have developed a process to mass-produce quantum dot micropillar cavities using direct-write lithography. This technique allows us to achieve mass patterning of high-aspect ratio pillars with vertical, smooth sidewalls maintaining a high quality factor for diameters below 2.0 μm. Encapsulating the cavities in a thin layer of oxide (Ta2O5) prevents oxidation in the atmosphere, preserving the optical properties of the cavity over months of ambient exposure. We confirm that single dots in the cavities can be deterministically excited to create high-purity indistinguishable single photons with interference visibility ( 0.941 ± 0.008 ) . © 2023 Author(s).
