1. Imaging the dynamics of individually adsorbed molecules.
- Author
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Schaffert, Johannes, Cottin, Maren C., Sonntag, Andreas, Karacuban, Hatice, Bobisch, Christian A., Lorente, Nicolás, Gauyacq, Jean-Pierre, and Möller, Rolf
- Subjects
MOLECULAR dynamics ,PARTICLE motion ,FLUCTUATIONS (Physics) ,TELEGRAPH & telegraphy ,COPPER phthalocyanine ,ELECTRONIC structure - Abstract
Although noise is observed in many experiments, it is rarely used as a source of information. However, valuable information can be extracted from noisy signals. The motion of particles on a surface induced, for example, by thermal activation or by the interaction with the tip of a scanning tunnelling microscope may lead to fluctuations or switching of the tunnelling current. The analysis of these processes gives insight into dynamics on a single atomic or molecular level. Unfortunately, scanning tunnelling microscopy (STM) is not a useful tool to study dynamics in detail, as it is an intrinsically slow technique. Here, we show that this problem can be solved by providing a full real-time characterization of random telegraph noise in the current signal. The hopping rate, the noise amplitude and the relative occupation of the involved states are measured as a function of the tunnelling parameters, providing spatially resolved maps. In contrast to standard STM, our technique gives access to transiently populated states revealing an electron-driven hindered rotation between the equilibrium and two metastable positions of an individually adsorbed molecule. The new approach yields a complete characterization of copper phthalocyanine molecules on Cu(111), ranging from dynamical processes on surfaces to the underlying electronic structure on the single-molecule level. [ABSTRACT FROM AUTHOR]
- Published
- 2013
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