Abstract EN:

This thesis is dedicated to investigating spin-dependent electrical properties of magnetic contacts of a few atoms. New properties are expected when reducing the size of magnetic contacts down. We developed an original and sophisticated setup for fabricating and measuring electrical transport through such ultimate nano-sized materials. Samples were obtained by a combination of top down technologies related to patterning the initial 2 electrodes, with bottom-up construction, involving electrochemistry to close-up the distance and size down to atomic size values. We used a lab on chip approach, taking advantage of microfluidics to control the flow and presence of the electrolytic solution. This whole setup was inserted into an electromagnet. This allowed fast setting of magnetic field amplitude and orientation, under possible variable temperature environment. Atomic-size junctions were successfully obtained for several materials: Ag, Au , Ni Co, Pt, and magnetoresistance properties of Ni contacts were systematically investigated. Measurements revealed anisotropic magnetoresistance properties, of magnitudes much larger than bulk intrinsic values. One third of the samples exhibited huge change of resistance under applied magnetic field orientation. We unambiguously indentified the paramagnetic metal ions as the origin of this huge eftect. This provides novel insight into a debate in the community that had excluded this observation under the assumption that it is aftected by mechanical artifacts. Investigations on Pt contacts and on samples combining mechanical break junctions and electrochemistry junctions confirmed the peculiar role played by the electrochemical environment.