Quantum Dots/Rods, Lamellar and Perovskite Semiconductors. Electronic Band Structure, Spin-Orbit, Angular Momentum, Spinors. Single-, Charged and Multiple Excitons, Polarons, Plasmons, Phonons, Electron-Hole Spin Exchange Coupling, Hyperfine and Overhauser Effect, Relaxation (Radiative, Auger, Trapping), Spin Coherence. Colloidal Chemistry, Vapor Transport and Spray Deposition. Optical, Magneto-Optics, Optically Detected Magnetic Resonance, Second-Order Photon Correlation Methods.

Learning Outcomes
At the End of the Course, the Student Should Understand the Fundamental Principal Which Endow Materials with Special Physical Properties (E.G., Discrete Electronic State, Long Coherence Time) That Are Suitable for Quantum Information Or Memory Devices. Furthermore, the Student Will Be Acquainted with Fabrication Procedures That Control the Physical Properties of Materials with Potential Application for Quantum Technology. the Students Will Also Learn About Various Physical Methodologies Most Suitable for Characterization of Optical and Magneto-Optical Properties, and Will Be Aware of the Challenges and Obstacles for Implementation of Artificial Materials in Quantum Technologies.