Marco A. Cabassi scite author profile

Developing a fundamental understanding of molecular conduction in different device environments is essential to the advance of molecular electronics. We show through a quantitative comparison of two types of junctions with the same molecule - one based on an isolated individual molecule and the other on a self-assembled monolayer - that intrinsic differences in the conduction per molecule as large as several orders of magnitude can exist simply as a function of the presence or absence of neighboring molecules. This behavior can be understood on the basis of thermal and electrostatic effects that depend critically on the local molecular environment. These results will help to unify data obtained from disparate device structures and to provide an improved basis for designing future molecular electronic devices.

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Thermally Activated Conduction in Molecular Junctions

Selzer

et al. 2004

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Marco A. Cabassi

Effect of Local Environment on Molecular Conduction: Isolated Molecule versus Self-Assembled Monolayer

Thermally Activated Conduction in Molecular Junctions

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