Molecular three-terminal devices: Fabrication and measurements

Herre S.J. Van Der Zant; Yann Vai Kervennic; Menno Poot; Kevin O'Neill; Zeger De Groot; Jos M. Thijssen; Hubert B. Heersche; Nicolai Stuhr-Hansen; Thomas Bjørnholm; Daniel Vanmaekelbergh; Cornelis A. Van Walree; Leonardus W. Jenneskens

doi:10.1039/b506240n

Molecular three-terminal devices: Fabrication and measurements

Herre S.J. Van Der Zant, Yann Vai Kervennic, Menno Poot, Kevin O'Neill, Zeger De Groot, Jos M. Thijssen, Hubert B. Heersche, Nicolai Stuhr-Hansen, Thomas Bjørnholm, Daniel Vanmaekelbergh, Cornelis A. Van Walree, Leonardus W. Jenneskens

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

96 Zitate (Scopus)

Abstract

Incorporation of a third, gate electrode in the device geometry of molecular junctions is necessary to identify the transport mechanism. At present, the most popular technique to fabricate three-terminal molecular devices makes use of electromigration. Although it is a statistical process, we show that control over the gap resistance can be obtained. A detailed analysis of the current-voltage characteristics of gaps without molecules, however, shows that they reveal features that can mistakenly be attributed to molecular transport. This observation raises questions about which gaps with molecules can be disregarded and which not. We show that electrical characteristics can be controlled by the rational design of the molecular bridge and that vibrational modes probed by electrical transport are of potential interest as molecular fingerprints.

Originalsprache	Englisch
Seiten (von - bis)	347-356
Seitenumfang	10
Fachzeitschrift	Faraday Discussions
Jahrgang	131
DOIs	https://doi.org/10.1039/b506240n
Publikationsstatus	Veröffentlicht - 2006
Extern publiziert	Ja

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10.1039/b506240n

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title = "Molecular three-terminal devices: Fabrication and measurements",

abstract = "Incorporation of a third, gate electrode in the device geometry of molecular junctions is necessary to identify the transport mechanism. At present, the most popular technique to fabricate three-terminal molecular devices makes use of electromigration. Although it is a statistical process, we show that control over the gap resistance can be obtained. A detailed analysis of the current-voltage characteristics of gaps without molecules, however, shows that they reveal features that can mistakenly be attributed to molecular transport. This observation raises questions about which gaps with molecules can be disregarded and which not. We show that electrical characteristics can be controlled by the rational design of the molecular bridge and that vibrational modes probed by electrical transport are of potential interest as molecular fingerprints.",

author = "{Van Der Zant}, {Herre S.J.} and Kervennic, {Yann Vai} and Menno Poot and Kevin O'Neill and {De Groot}, Zeger and Thijssen, {Jos M.} and Heersche, {Hubert B.} and Nicolai Stuhr-Hansen and Thomas Bj{\o}rnholm and Daniel Vanmaekelbergh and {Van Walree}, {Cornelis A.} and Jenneskens, {Leonardus W.}",

year = "2006",

doi = "10.1039/b506240n",

language = "English",

volume = "131",

pages = "347--356",

journal = "Faraday Discussions",

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AU - Van Der Zant, Herre S.J.

AU - Kervennic, Yann Vai

AU - Poot, Menno

AU - O'Neill, Kevin

AU - De Groot, Zeger

AU - Thijssen, Jos M.

AU - Heersche, Hubert B.

AU - Stuhr-Hansen, Nicolai

AU - Bjørnholm, Thomas

AU - Vanmaekelbergh, Daniel

AU - Van Walree, Cornelis A.

AU - Jenneskens, Leonardus W.

PY - 2006

Y1 - 2006

N2 - Incorporation of a third, gate electrode in the device geometry of molecular junctions is necessary to identify the transport mechanism. At present, the most popular technique to fabricate three-terminal molecular devices makes use of electromigration. Although it is a statistical process, we show that control over the gap resistance can be obtained. A detailed analysis of the current-voltage characteristics of gaps without molecules, however, shows that they reveal features that can mistakenly be attributed to molecular transport. This observation raises questions about which gaps with molecules can be disregarded and which not. We show that electrical characteristics can be controlled by the rational design of the molecular bridge and that vibrational modes probed by electrical transport are of potential interest as molecular fingerprints.

AB - Incorporation of a third, gate electrode in the device geometry of molecular junctions is necessary to identify the transport mechanism. At present, the most popular technique to fabricate three-terminal molecular devices makes use of electromigration. Although it is a statistical process, we show that control over the gap resistance can be obtained. A detailed analysis of the current-voltage characteristics of gaps without molecules, however, shows that they reveal features that can mistakenly be attributed to molecular transport. This observation raises questions about which gaps with molecules can be disregarded and which not. We show that electrical characteristics can be controlled by the rational design of the molecular bridge and that vibrational modes probed by electrical transport are of potential interest as molecular fingerprints.

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Molecular three-terminal devices: Fabrication and measurements

Abstract

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