Stanowski, R.W

Stanowski, R.W, “Nano-ingéniérie de bande interdite des semiconducteurs quantiques par recuit thermique rapide au laser“, PhD in Electrical Engineering, 2011, Université de Sherbrooke, Sherbrooke, Canada. [pdf]

The ability to fabricate semiconductor wafers with spatially selected regions of different bandgap material is required for the fabrication of monolithic photonic integrated circuits (PIC‟s). Although this subject has been studied for three decades and many semiconductor engineering approaches have been proposed, the problem of achieving reproducible results has constantly challenged scientists and engineers. This concerns not only the techniques relaying on multiple sequential epitaxial growth and selective area epitaxy, but also the conventional quantum well intermixing (QWI) technique that has been investigated as a post-growth approach for bandgap engineering. Among different QWI techniques, those based on the use of different lasers appear to be attractive in the context of high-precision and the potential for cost-effective bandgap engineering. For instance, a tightly focused beam of the infrared (IR) laser could be used for the annealing of small regions of a semiconductor wafer comprising different quantum well (QW) or quantum dot (QD) microstructures. The precision of such an approach in delivering wafers with well defined regions of different bandgap material will depend on the ability to control the laser-induced temperature, dynamics of the heating-cooling process and the ability to take advantage of the bandgap engineering diagnostics.

In the frame of this thesis, I have investigated IR laser-induced QWI processes in QW wafers comprising GaAs/AlGaAs and InP/InGaAsP microstructures and in InAs QD microstructures grown on InP substrates. For that purpose, I have designed and set up a 2-laser system for selective area rapid thermal annealing (Laser-RTA) of semiconductor wafers. The advantage of such an approach is that it allows carrying out annealing with heating-cooling rates unattainable with conventional RTA techniques, while a tightly focused beam of one of the IR lasers is used for „spot annealing‟. These features have enabled me to introduce a new method for iterative bandgap engineering at selected areas (IBESA) of semiconductor wafers. The method proves the ability to deliver both GaAs and InP based QW/QD wafers with regions of different bandgap energy controlled to better than ± 1nm of the spectral emission wavelength. The IBESA technique could be used for tuning the optical characteristics of particular regions of a QW wafer prepared for the fabrication of a PIC. Also, this approach has the potential for tuning the emission wavelength of individual QDs in wafers designed, e.g., for the fabrication of single photon emitters.

Walid M. Hassen, Jonathan Vermette, Houman Moteshareie, Azam F. Tayabali, Jan J. Dubowski, “Semi-automated water sampling module for repeated sampling and concentration of Bacillus cereus group spores”, Scientific Reports (Nature), 13:831 (2023).

Houman Moteshareie, Walid M. Hassen, Yasmine Dirieh, Emma Groulx, Jan J. Dubowski, Azam F. Tayabali, “Rapid, Sensitive, and Selective Quantification of Bacillus cereus Spores Using xMAP Technology”, Microorganisms 10(7), 1408 (2022).

Juliana Chawich, Walid M. Hassen, Amanpreet Singh, Daniela T. Marquez, Maria C. DeRosa, Jan J. Dubowski, “Polymer Brushes on GaAs and GaAs/AlGaAs Nanoheterostructures: A Promising Platform for Attractive Detection of Legionella pneumophila“, ACS Omega 7, 33349-33357 (2022).

Lucas Paladines, Walid M. Hassen, Juliana Chawich, Stefan Dübel, Simon Lévesque, Jan J. Dubowski, Eric H. Frost, “Investigation of Conditions for Capture of Live Legionella pneumophila with Polyclonal and Recombinant Antibodies”, Biosensors 12, 380 (2022).