Two-Terminal nanoelectromechanical devices based on germanium nanowires

Jana Andzane; Nikolay Petkov; Aleksandrs I. Livshits; John J. Boland; Justin D. Holmes; Donats Erts

doi:10.1021/nl8037807

Two-Terminal nanoelectromechanical devices based on germanium nanowires

Jana Andzane
, Nikolay Petkov
, Aleksandrs I. Livshits
, John J. Boland
, Justin D. Holmes
, Donats Erts

School of Chemistry

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

Abstract

A two-terminal bistable device, having both ON and OFF regimes, has been demonstrated with Ge nanowires using an in situ TEM-STM technique. The function of the device is based on delicately balancing electrostatic, elastic, and adhesion forces between the nanowires and the contacts, which can be controlled by the applied voltage. The operation and failure conditions of the bistable device were investigated, i.e. the influence of nanowire diameter, the surface oxide layer on the nanowires and the current density. During ON/OFF cycles the Ge nanowires were observed to be more stable than carbon nanotubes, working at similar conditions, due to the higher mechanical stability of the nanowires. The higher resistivity of Ge nanowires, compared to carbon nanotubes, provides potential application of these 1D nanostructures in high-voltage devices.

Original language	English
Pages (from-to)	1824-1829
Number of pages	6
Journal	Nano Letters
Volume	9
Issue number	5
DOIs	https://doi.org/10.1021/nl8037807
Publication status	Published - 13 May 2009

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title = "Two-Terminal nanoelectromechanical devices based on germanium nanowires",

abstract = "A two-terminal bistable device, having both ON and OFF regimes, has been demonstrated with Ge nanowires using an in situ TEM-STM technique. The function of the device is based on delicately balancing electrostatic, elastic, and adhesion forces between the nanowires and the contacts, which can be controlled by the applied voltage. The operation and failure conditions of the bistable device were investigated, i.e. the influence of nanowire diameter, the surface oxide layer on the nanowires and the current density. During ON/OFF cycles the Ge nanowires were observed to be more stable than carbon nanotubes, working at similar conditions, due to the higher mechanical stability of the nanowires. The higher resistivity of Ge nanowires, compared to carbon nanotubes, provides potential application of these 1D nanostructures in high-voltage devices.",

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doi = "10.1021/nl8037807",

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T1 - Two-Terminal nanoelectromechanical devices based on germanium nanowires

AU - Andzane, Jana

AU - Petkov, Nikolay

AU - Livshits, Aleksandrs I.

AU - Boland, John J.

AU - Holmes, Justin D.

AU - Erts, Donats

PY - 2009/5/13

Y1 - 2009/5/13

N2 - A two-terminal bistable device, having both ON and OFF regimes, has been demonstrated with Ge nanowires using an in situ TEM-STM technique. The function of the device is based on delicately balancing electrostatic, elastic, and adhesion forces between the nanowires and the contacts, which can be controlled by the applied voltage. The operation and failure conditions of the bistable device were investigated, i.e. the influence of nanowire diameter, the surface oxide layer on the nanowires and the current density. During ON/OFF cycles the Ge nanowires were observed to be more stable than carbon nanotubes, working at similar conditions, due to the higher mechanical stability of the nanowires. The higher resistivity of Ge nanowires, compared to carbon nanotubes, provides potential application of these 1D nanostructures in high-voltage devices.

AB - A two-terminal bistable device, having both ON and OFF regimes, has been demonstrated with Ge nanowires using an in situ TEM-STM technique. The function of the device is based on delicately balancing electrostatic, elastic, and adhesion forces between the nanowires and the contacts, which can be controlled by the applied voltage. The operation and failure conditions of the bistable device were investigated, i.e. the influence of nanowire diameter, the surface oxide layer on the nanowires and the current density. During ON/OFF cycles the Ge nanowires were observed to be more stable than carbon nanotubes, working at similar conditions, due to the higher mechanical stability of the nanowires. The higher resistivity of Ge nanowires, compared to carbon nanotubes, provides potential application of these 1D nanostructures in high-voltage devices.

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DO - 10.1021/nl8037807

M3 - Article

AN - SCOPUS:66449099313

SN - 1530-6984

VL - 9

SP - 1824

EP - 1829

JO - Nano Letters

JF - Nano Letters

IS - 5

ER -

Two-Terminal nanoelectromechanical devices based on germanium nanowires

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