Current-driven dynamics in quantum electronics

Tamar Seideman

doi:10.1080/09500340308233571

Current-driven dynamics in quantum electronics

Tamar Seideman^*

^*Corresponding author for this work

Chemistry

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

We suggest that inelastic electron tunnelling via molecular-scale electronics can induce a variety of fascinating dynamic processes in the molecular moiety. These include vibration, rotation, intermode energy flow and reaction. Potential applications of current-induced dynamics in molecular-scale devices range from new forms of molecular machines and approaches to enhancing the conductivity of molecular wires, to new directions in nanochemistry and nanolithography. Understanding the molecular properties that encourage current-triggered dynamics is relevant also to the design of devices that would be guaranteed to remain stable under current. We discuss the qualitative physics underlying current-driven dynamics, briefly sketch a theory developed to explore these dynamics, describe a few examples from recent and ongoing numerical work and note avenues for future research.

Original language	English (US)
Pages (from-to)	2393-2410
Number of pages	18
Journal	Journal of Modern Optics
Volume	50-15
Issue number	17
DOIs	https://doi.org/10.1080/09500340308233571
State	Published - 2003

ASJC Scopus subject areas

Atomic and Molecular Physics, and Optics

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10.1080/09500340308233571

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title = "Current-driven dynamics in quantum electronics",

abstract = "We suggest that inelastic electron tunnelling via molecular-scale electronics can induce a variety of fascinating dynamic processes in the molecular moiety. These include vibration, rotation, intermode energy flow and reaction. Potential applications of current-induced dynamics in molecular-scale devices range from new forms of molecular machines and approaches to enhancing the conductivity of molecular wires, to new directions in nanochemistry and nanolithography. Understanding the molecular properties that encourage current-triggered dynamics is relevant also to the design of devices that would be guaranteed to remain stable under current. We discuss the qualitative physics underlying current-driven dynamics, briefly sketch a theory developed to explore these dynamics, describe a few examples from recent and ongoing numerical work and note avenues for future research.",

author = "Tamar Seideman",

note = "Funding Information: The author is grateful to several postdoctoral fellows and colleagues who contributed to the work reviewed in this article, in particular Dr Saman Alavi, Dr Roger Rousseau and Professor Hong Guo. This work was partially supported by the Natural Science and Engineering Research Council of Canada.",

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N1 - Funding Information: The author is grateful to several postdoctoral fellows and colleagues who contributed to the work reviewed in this article, in particular Dr Saman Alavi, Dr Roger Rousseau and Professor Hong Guo. This work was partially supported by the Natural Science and Engineering Research Council of Canada.

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N2 - We suggest that inelastic electron tunnelling via molecular-scale electronics can induce a variety of fascinating dynamic processes in the molecular moiety. These include vibration, rotation, intermode energy flow and reaction. Potential applications of current-induced dynamics in molecular-scale devices range from new forms of molecular machines and approaches to enhancing the conductivity of molecular wires, to new directions in nanochemistry and nanolithography. Understanding the molecular properties that encourage current-triggered dynamics is relevant also to the design of devices that would be guaranteed to remain stable under current. We discuss the qualitative physics underlying current-driven dynamics, briefly sketch a theory developed to explore these dynamics, describe a few examples from recent and ongoing numerical work and note avenues for future research.

AB - We suggest that inelastic electron tunnelling via molecular-scale electronics can induce a variety of fascinating dynamic processes in the molecular moiety. These include vibration, rotation, intermode energy flow and reaction. Potential applications of current-induced dynamics in molecular-scale devices range from new forms of molecular machines and approaches to enhancing the conductivity of molecular wires, to new directions in nanochemistry and nanolithography. Understanding the molecular properties that encourage current-triggered dynamics is relevant also to the design of devices that would be guaranteed to remain stable under current. We discuss the qualitative physics underlying current-driven dynamics, briefly sketch a theory developed to explore these dynamics, describe a few examples from recent and ongoing numerical work and note avenues for future research.

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Current-driven dynamics in quantum electronics

Abstract

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