Theoretical investigation of magneto-optical and many-body phenomena in quasi-two-dimensional systems of quantum dots and rings

Nanostructures that exhibit unique properties in quasi-two-dimensional configurations play a crucial role in exploring fundamental quantum phenomena. These structures hold promise across diverse fields such as light and particle sensing, photonics, and quantum computing. Introducing a tailored magnetic field to these systems disrupts inherent symmetries, such as time-reversal symmetry, enabling the generation of novel effects associated with magnetic phase interference phenomena. This breakthrough opens up new perspectives for advancing the manipulation of magneto-optical responses and light-matter interactions in quasi-two-dimensional structures. This research project aims to explore the underlying physical mechanisms driving these phenomena and to develop strategies for controlling the magneto-optical, charge and spin-transport properties of arrayed structures of planar quantum rings (QRs), as well as the light-matter nonlinear interactions in these structures. Advanced computational techniques, including Exact Diagonalization, Hartree-Fock Approximation and Density Functional Theory (DFT) will be employed to deepen our understanding and pave the way for future quantum technologies by leveraging the peculiarities of the quantum world.