A selected list of main achievements within the project include:
1. Analysis of measurements of thermal conductance of edge states in putative non-abelian fractional quantum Hall states.
2. Theoretical analysis of the effect of disorder on the phase diagram of the \nu=5/2 FQHE state and the way it is reflected in measurements of thermal Hall conductance.
3. Proposals for new experimental set-ups for the realization of Majorana zero modes in the normal part in planar SNS junctions, and participation in the analysis of the experimental systems realizing the proposal.
4. Study of interacting one dimensional systems and the circumstances under which they exhibit fractional conductances and fractional charge. The fate of these wires in presence of a nearby strongly correlated system inducing attractive interaction between the electrons in the one dimensional system.
5. Study of interference effects in the ultraclean materials of delafossites family, in Fabry-Perot interferometers in the fractional quantum Hall effect, in Majorana wire networks, and in time-domain set-ups.
6. Constructing a model describing the evolution of the correlated quantum states in twisted bi-layer Graphene systems and employing it to understand a set of experimental measurements of thermodynamic quantities conducted by colleagues at MIT and Weizmann institute
7. Discovery of a class of experimental set-ups in which 1D topological superconductivity may be generated with no application of a Zeeman magnetic field, thus finding a solution to an experimentally timely problem.
8. Analyzing an extension of this set-up to 2D.
9. Employing composite fermion theory to analyze the phases of the half-filled Chern band.
10. Developing an online course on Topological Quantum Matter that is followed by thousands of researchers, including students and faculty members. See
https://www.youtube.com/watch?v=q0ELfyrvnbQ&t=55s&ab_channel=Topologicalquantummatter-Weizmannonline%7d(öffnet in neuem Fenster) and
https://www.youtube.com/@topologicalquantummatter-w4105/featured(öffnet in neuem Fenster).