The NANOWHYR project aims at addressing the major challenges currently hampering efficient integration of QDs on Si, by using III-V QDs in semiconductors nanowires (NWs). NWs are rod-shaped semiconductors with diameters of few to dozens of nanometers and length of few micrometers. NWs can host site-controlled III-V QDs ideal for a post-growth integration to Si via pick-and-place techniques, and they can also be directly grown on Si with high quality.
NWs can be grown via a bottom-up, scalable approach. Their density, size, morphology, and chemical compositions can be finely controlled by modern growth techniques. Thanks to the NW capability to release strain at the NW free sidewalls, they can host heterostructures that can hardly be obtained in their planar counterparts. For similar reasons, NWs are typically free from long-range crystalline defects.
However, employing QDs in NWs as single photon sources involves several other challenges (improving tpurity, indistinguishability, efficiency etc.). The solution we propose to solve them is wide-ranging, as it can be implementated in both architectures: the hybrid configuration and the monolithic configuration.
The objectives of the NANOWHYR project are:
• Hybrid integration of a single dot-in-NW on a Si chip. The QD will emit single photons in a broad and tunable range (from near infrared to telecom λ). The chip can contain an artificial cavity, such as a photonic crystal, or a NW waveguide. The formation of the QD takes place via spatially controlled hydrogenation, namely by removing hydrogen via near field illumination or by selective hydrogenation of NW portions.
• Monolithic integration of a single, vertical III-V QD in a NW array, grown on mainstream Si substrates. The QD emits single photons with tunable energies as above. The quantum emitter can be formed via special heterostructure designs, during growth, or via interplay of hydrogenation and hydrogen removal post-growth, and it can be contained in cavities.
The target materials are dilute nitrides like GaAsN and InN. When InN and GaAsN are used, bandgap energy can be fine-tuned by hydrogenation. Alternative material systems, such as GaAsP and InAs-based QDs in NWs, are being investigated when QDs formed during growth are needed, such as to study hydrogen effect on QD intensity, NW waveguiding properties, benchmarking single-photon-emitters formed during growth, obtaining emitters at specific desired energies.