Abstract
The adsorption on KBr(001) of a specially designed molecule, consisting of a flat aromatic triphenylene core equipped with six flexible propyl chains ending with polar cyano groups, is investigated by using atomic force microscopy in the noncontact mode (NC-AFM) coupled to Kelvin probe force microscopy (KPFM) in ultrahigh vacuum at room temperature. Two types of monolayers are identified, one in which the molecules lie flat on the surface (MLh) and another in which they stand approximately upright (MLv). The Kelvin voltage on these two structures is negatively shifted relative to that of the clean KBr surface, revealing the presence of surface dipoles with a component pointing along the normal to the surface. These findings are interpreted with the help of numerical simulations. It is shown that the surface–molecule interaction is dominated by the electrostatic interaction of the cyano groups with the K+ ions of the substrate. The molecule is strongly adsorbed in the MLh structure with an adsorption energy of 1.8 eV. In the MLv layer, the molecules form π-stacked rows aligned along the polar directions of the KBr surface. In these rows, the molecules are less strongly bound to the substrate, but the structure is stabilized by the strong intermolecular interaction due to π-stacking.
Highlights
The study of molecular adsorption on atomically clean, welldefined surfaces of bulk insulators is progressing rapidly due to the development of atomic force microscopy in the noncontact mode [1,2,3,4,5,6,7,8,9,10,11,12,13]
The white dots that appear on the step edge have a size that is compatible with single molecules, but the resolution is not high enough for a convincing identification
We have demonstrated that HCPTP forms two types of monolayer on KBr(001): molecules lie flat on the surface (MLh) where the molecules are lying flat on the substrate and MLv where they stand upright
Summary
The study of molecular adsorption on atomically clean, welldefined surfaces of bulk insulators is progressing rapidly due to the development of atomic force microscopy in the noncontact (or frequency modulation) mode [1,2,3,4,5,6,7,8,9,10,11,12,13]. Its application to bulk insulating surfaces [24,25,26] is only beginning, and studies of molecular adsorption on these surfaces are still very scarce [6,8]. Coupling these two techniques is interesting for the characterization of the electrical properties of the adsorbates, and for the extraction of topographic images that are free from distortion induced by electrostatic forces [27]
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