Research | Collaborazioni Scientifiche | Seminari e Convegni

After the rise of graphene in 2010, the discovery of exotic topological phases has become the hinge of a revolutionary concept: The currents can be generated by using the electron spins. Such currents, the so-called spin-currents, offer innumerable advantages compared to the classical ones: They are protected against disorder and can be transported without backscattering of carriers. This minimizes the power that allows the electronic devices to work, enabling technology to operate at a considerably lower switching energy. In this context, investigating and manipulating the spins of the electrons constitutes a unique opportunity to stabilize exotic phases of quantum matter which are currently beyond reach and to understand the ones which are still significantly unexplored.

Photoemission, resolved in spin, is a gold standard technique to directly probe the electrons, their spins and to see how these couple to the orbital motions. Here, I will show how such a technique is able to detect the spin-driven properties of Kagomé systems, opening a potential pathway to exploit their electronic and magnetic phases for multifunctional applications. Finally I will show how to push this technique beyond the current state of the art and use it to measure the topological invariants, exemplified by the Berry phase.