Single-molecule electric revolving door

Liang Yan Hsu; Elise Y. Li; Herschel Rabitz

doi:10.1021/nl401340c

Single-molecule electric revolving door

Liang Yan Hsu^*
, Elise Y. Li
, Herschel Rabitz

^*Corresponding author for this work

Department of Chemistry

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

26 Citations (Scopus)

Abstract

This work proposes a new type of molecular machine, the single-molecule electric revolving door, which utilizes conductance dependence upon molecular conformation as well as destructive quantum interference. We perform electron transport simulations in the zero-bias limit using the Landauer formalism together with density functional theory. The simulations show that the open- and closed-door states, accompanied by significant conductance variation, can be operated by an external electric field. The large on-off conductance ratio (∼10⁵) implies that the molecular machine can also serve as an effective switching device. The simultaneous control and detection of the door states can function at the nanosecond scale, thereby offering a new capability for molecular-scale devices.

Original language	English
Pages (from-to)	5020-5025
Number of pages	6
Journal	Nano Letters
Volume	13
Issue number	11
DOIs	https://doi.org/10.1021/nl401340c
Publication status	Published - 2013 Nov 13

Keywords

Molecular machine
conductance
density-functional theory
molecular electronics
molecular switch
quantum transport

ASJC Scopus subject areas

Bioengineering
General Chemistry
General Materials Science
Condensed Matter Physics
Mechanical Engineering

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10.1021/nl401340c

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title = "Single-molecule electric revolving door",

abstract = "This work proposes a new type of molecular machine, the single-molecule electric revolving door, which utilizes conductance dependence upon molecular conformation as well as destructive quantum interference. We perform electron transport simulations in the zero-bias limit using the Landauer formalism together with density functional theory. The simulations show that the open- and closed-door states, accompanied by significant conductance variation, can be operated by an external electric field. The large on-off conductance ratio (∼105) implies that the molecular machine can also serve as an effective switching device. The simultaneous control and detection of the door states can function at the nanosecond scale, thereby offering a new capability for molecular-scale devices.",

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AU - Hsu, Liang Yan

AU - Li, Elise Y.

AU - Rabitz, Herschel

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Y1 - 2013/11/13

N2 - This work proposes a new type of molecular machine, the single-molecule electric revolving door, which utilizes conductance dependence upon molecular conformation as well as destructive quantum interference. We perform electron transport simulations in the zero-bias limit using the Landauer formalism together with density functional theory. The simulations show that the open- and closed-door states, accompanied by significant conductance variation, can be operated by an external electric field. The large on-off conductance ratio (∼105) implies that the molecular machine can also serve as an effective switching device. The simultaneous control and detection of the door states can function at the nanosecond scale, thereby offering a new capability for molecular-scale devices.

AB - This work proposes a new type of molecular machine, the single-molecule electric revolving door, which utilizes conductance dependence upon molecular conformation as well as destructive quantum interference. We perform electron transport simulations in the zero-bias limit using the Landauer formalism together with density functional theory. The simulations show that the open- and closed-door states, accompanied by significant conductance variation, can be operated by an external electric field. The large on-off conductance ratio (∼105) implies that the molecular machine can also serve as an effective switching device. The simultaneous control and detection of the door states can function at the nanosecond scale, thereby offering a new capability for molecular-scale devices.

KW - Molecular machine

KW - conductance

KW - density-functional theory

KW - molecular electronics

KW - molecular switch

KW - quantum transport

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SP - 5020

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JO - Nano Letters

JF - Nano Letters

IS - 11

ER -

Single-molecule electric revolving door

Abstract

Keywords

ASJC Scopus subject areas

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