Adsorption of single 1,8-octanedithiol molecules on Cu(100).

Single 1,8-octanedithiol (ODT) molecules adsorbed onto the Cu(100) surface have been characterized by using scanning tunneling microscopy (STM) and studied by semi-empirical calculations. STM images have revealed two types of chiral molecules on the surface upon adsorption and both types of molecules showed two bright spots at the extremities of a small rod due to the enhanced electronic density contrast of the chemisorbed sulfur atoms. In sub-monolayer regime deposition, ODT molecules exhibit preferential adsorption directions and the relaxation mechanism is driven by the chemisorption of the two sulfur atoms in a hollow site of the surface. By means of calculations several conformations of the molecule according to the energetically favorable alkane body stretching constraint have been studied. The comparison between relaxed conformations and between calculated and experimental STM images, followed by an analysis of different orientations, has allowed determining unambiguously the most favorable position of the ODT molecule on Cu(100).

Graphite, graphene on SiC, and graphene nanoribbons: Calculated images with a numerical FM-AFM.

BACKGROUND: Characterization at the atomic scale is becoming an achievable task for FM-AFM users equipped, for example, with a qPlus sensor. Nevertheless, calculations are necessary to fully interpret experimental images in some specific cases. In this context, we developed a numerical AFM (n-AFM) able to be used in different modes and under different usage conditions. RESULTS: Here, we tackled FM-AFM image calculations of three types of graphitic structures, namely a graphite surface, a graphene sheet on a silicon carbide substrate with a Si-terminated surface, and finally, a graphene nanoribbon. We compared static structures, meaning that all the tip and sample atoms are kept frozen in their equilibrium position, with dynamic systems, obtained with a molecular dynamics module allowing all the atoms to move freely during the probe oscillations. CONCLUSION: We found a very good agreement with experimental graphite and graphene images. The imaging process for the deposited nanoribbon demonstrates the stability of our n-AFM to image a non-perfectly planar substrate exhibiting a geometrical step as well as a material step.