Current-driven dynamics in molecular-scale devices

From National Research Council Canada

DOI	Resolve DOI: https://doi.org/10.1088/0953-8984/15/14/201
Author	Search for: Seideman, Tamar
Format	Text, Article
Abstract	We review recent theoretical work on current-triggered processes in molecular-scale devices - a field at the interface between solid state physics and chemical dynamics with potential applications in diverse areas, including artificial molecular machines, unimolecular transport, surface nanochemistry and nanolithography. The qualitative physics underlying current-triggered dynamics is first discussed and placed in context with several well-studied phenomena with which it shares aspects. A theory for modelling these dynamics is next formulated within a time-dependent scattering approach. Our end result provides useful insight into the system properties that determine the reaction outcome as well as a computationally convenient framework for numerical realization. The theory is applied to study single-molecule surface reactions induced by a scanning tunnelling microscope and current-triggered dynamics in single-molecule transistors. We close with a discussion of several potential applications of current-induced dynamics in molecular devices and several opportunities for future research.
Publication date	2003
In	Journal of Physics: Condensed Matter 15 (2003): R521–R549.
Language	English
NRC publication	This is a non-NRC publication "Non-NRC publications" are publications authored by NRC employees prior to their employment by NRC.
NPARC number	12327816
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Record identifier	ad94aba0-52e0-4f28-94e7-04f842fd99bb
Record created	2009-09-10
Record modified	2020-04-02

Date modified:: 2024-04-19