"The work performed during the project can be summarized in the following tasks:
1-Characterization of the electrical conductance of multi-terminal metallic ""Josephson"" junctions (namely: the omaga-SQUIPT).
I fabricated a nanoscopic T-shape island of copper embedded in two superconducting loops of aluminium (see Fig.1). By measuring, at ultra-low temperature, electrical conductance of the copper island in contact to a metallic aluminium-manganese probe I was able to demonstrate the fine control and exotic quantum states generated in the conducting island when an external magnetic field is applied. Moreover, I developed a theoretical model able to demonstrate the unusual properties of these quantum states. Finally, I was able to extend the operating temperatures of the device from 1 Kelvin up to 3 Kelvin by adding a vanadium layer on top of the aluminium loop.
2-Study of the anomalous superconducting current in indium arsenide nanowires.
I realized a nanoscopic “Josephson” junction with an indium arsenide nanowire contacted by two aluminium leads. By measuring the amplitude of the electrical superconducting current as a function of the external magnetic field I observed clear signatures of the unconventional quantum states enabling fault-tolerant quantum computing scheme.
3-Development of a molecular doping in different materials
I extended, in collaboration with Twente University, the molecular doping technique to cover a larger spectrum of materials. Specifically we found a recipe based on a different chemical compositions of the molecule able to efficiently cover the oxide surface of conventional silicon wafers. The thin copper films evaporated on top of these active surfaces showed at low temperature characteristic feature in the electrical conductance demonstrating the magnetic doping induced by the molecular layer.
4-Understanding the magnetic properties of europium-sulphide/aluminium bilayers
I measured the electrical conductance of thin films made of europium-sulphide/aluminium bilayers in electrical contact with an aluminium probe. The evolution of the electrical conductance as a function of an external magnetic field allowed me to understand the dynamics of the ferromagnetism of this unconventional bilayer. I then developed a theoretical model able to describe the electrical properties of the bilayer and deeply understand the interplay between the magnetism of the europium-sulphide and the superconductivity of the Aluminium layer.
All these results have been disseminated in the major international conference dedicated to superconductivity magnetism and unconventional state of matter, as well as public events organized by my institute. They represents an important step towards the understanding of robust quantum states of matter for the realization of fault-tolerant quantum computers. Moreover, in the short term, the patent I submitted during this project could be immediately exploited in the implementation of modern supercomputers.
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