Abstract EN:

In this research work we carried out experimental studies of insulating surfaces and insulating thin films surfaces by scanning probe microscopy techniques under ultra vacuum at room temperature. In particular we used Scanning Tunneling Microscopy (STM) and Atomic Force Microscopy in the non contact mode (NC-AFM). We present experimental results on two systems: the insulating surface KBr (001) and the thin insulating alumina film formed by oxidation of the (110) surface of a NiAl crystal. Initially, we modified the STM/AFM head by changing the optical device of the detection of the cantilever oscillations system. This crucial improvement enabled us to carry out a series of experiments on the (001) cleaved surface of the ionic crystal KBr at the atomic level. We have evidence obtained from atomic resolution images, that shows a change in contrast when the tip passes through a step edge. Where we could observe a systematic and reversible change in the contrasts of the image. These observations were interpreted in terms of the atomic displacements of the last extremity tip apex, involving the change of last ion sign. This change of ion determines the type of image observed at atomic resolution. This assumption was confirmed by analyzing the experimental curves giving the force between the tip and the surface according to the tip to surface distance. This study was followed of some attempts to images organic molecules on this insulating surface. The Pd/Al10O13/NiAl (110) system was explored by STM and scanning tunneling spectroscopy (STS), where the oxide layer is formed by exposing the NiAl(110) surface to an oxygen atmosphere, while keeping the sample temperature at (~280°C) under ultra-high vacuum. The atomic resolution images obtained enabled us to go down into the atomic structure of the insulating alumina layer, with stoichiometry Al10O13. In addition, it could be possible to atomically resolve a unit cell of one type of defects formed. We also carried out electrical measurements in order to characterize its electric properties on a nanometer scale. . .