Manipulation of Organic Molecules by AFM
The adsorption of organic molecules on patterned surfaces has become a subject of intensive
study motivated by the prospect of hybrid molecular electronic devices. The operation of such
devices is ultimately governed by the electronic properties of single or little clusters of
molecules. Investigating and modifying the arrangement of organic aggregates on different
surfaces is therefore a primary goal in molecular electronics. Whereas organic molecules on
metals have been repeatedly observed by STM, only few groups observed their disposal on
insulating surfaces by AFM. Figure 1 shows the first ordered arrangement of organic molecules
observed on a nanostructured insulator by our group. The substrate is a KBr crystal, where
rectangular pits, acting as molecular traps, were previously created by electron irradiation [1].
The probing tip can be used not only to image, but also to manipulate molecules on a surface.
One of the first examples of nanomanipulation was given by Jung et al., who displaced porphyrin
molecules across a copper surface with an STM tip [2]. We are currently studying the same
molecules on copper surfaces by AFM. In some cases porphyrin molecules slightly move while
scanning (Figure 2). In other cases the displacement is dramatic and “molecular trajectories”
can be recognized. In both cases, AFM allows to determine the mechanical forces acting between
tip and molecules, which is not possible by STM.
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Figure 1: First experimental observation of organic molecules (subphthalocyanines) trapped in rectangular holes. |
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Figure 2:Porphyrin molecules on a copper surface investigated by AFM. Note that some molecules changed their position in the two frames. |
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[1] |
Observation of Individual Molecules Trapped on a Nanostructured Insulator
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[2] |
Controlled Room-Temperature Positioning of Individual Molecules: Molecular Flexure and Motion
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Contact:
Enrico Gnecco |
Ernst Meyer |
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