Planar nanogap electrodes by direct nanotransfer printing

Sebastian Strobel; Stefan Harrer; Guillermo Penso Blanco; Giuseppe Scarpa; Gerhard Abstreiter; Paolo Lugli; Marc Tornow

doi:10.1002/smll.200801400

Planar nanogap electrodes by direct nanotransfer printing

Sebastian Strobel, Stefan Harrer, Guillermo Penso Blanco, Giuseppe Scarpa, Gerhard Abstreiter, Paolo Lugli, Marc Tornow

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

24 Scopus citations

Abstract

The fabrication of planar nanogap electrodes on a silicon substrate, using direct high-resolution metal nanotransfer printing (nTP) was investigated. Molecular beam epitaxy (MBE) molds were obtained by growing a single-crystalline AlGaAs layer of micrometer thickness on top of a GaAs substrate wafer, followed by either a single, thick GaAs layer or by a sequence of alternating GaAs and AlGaAs layers, followed by a second, micrometer-thick AlGaAs layer. All these mentioned layers were separated by 100-nm-wide support structures of the opposite material. Single-line molds were fabricated from a heterostructure comprising two 2-p.m-thick AlGaAs planes on either side of a buried 10-nm-thick GaAs layer. Subsequent to selective etching, the samples were flushed with deionized water and blown dry with nitrogen. Electrical shorts were experienced despite the SEM inspection, indicating the presence of a gap.

Original language	English
Pages (from-to)	579-582
Number of pages	4
Journal	Small
Volume	5
Issue number	5
DOIs	https://doi.org/10.1002/smll.200801400
State	Published - 6 Mar 2009

Keywords

Heterostructures
Molecular electronics
Nanogap electrodes
Nanotransfer printing

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10.1002/smll.200801400

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title = "Planar nanogap electrodes by direct nanotransfer printing",

abstract = "The fabrication of planar nanogap electrodes on a silicon substrate, using direct high-resolution metal nanotransfer printing (nTP) was investigated. Molecular beam epitaxy (MBE) molds were obtained by growing a single-crystalline AlGaAs layer of micrometer thickness on top of a GaAs substrate wafer, followed by either a single, thick GaAs layer or by a sequence of alternating GaAs and AlGaAs layers, followed by a second, micrometer-thick AlGaAs layer. All these mentioned layers were separated by 100-nm-wide support structures of the opposite material. Single-line molds were fabricated from a heterostructure comprising two 2-p.m-thick AlGaAs planes on either side of a buried 10-nm-thick GaAs layer. Subsequent to selective etching, the samples were flushed with deionized water and blown dry with nitrogen. Electrical shorts were experienced despite the SEM inspection, indicating the presence of a gap.",

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AU - Strobel, Sebastian

AU - Harrer, Stefan

AU - Blanco, Guillermo Penso

AU - Scarpa, Giuseppe

AU - Abstreiter, Gerhard

AU - Lugli, Paolo

AU - Tornow, Marc

PY - 2009/3/6

Y1 - 2009/3/6

N2 - The fabrication of planar nanogap electrodes on a silicon substrate, using direct high-resolution metal nanotransfer printing (nTP) was investigated. Molecular beam epitaxy (MBE) molds were obtained by growing a single-crystalline AlGaAs layer of micrometer thickness on top of a GaAs substrate wafer, followed by either a single, thick GaAs layer or by a sequence of alternating GaAs and AlGaAs layers, followed by a second, micrometer-thick AlGaAs layer. All these mentioned layers were separated by 100-nm-wide support structures of the opposite material. Single-line molds were fabricated from a heterostructure comprising two 2-p.m-thick AlGaAs planes on either side of a buried 10-nm-thick GaAs layer. Subsequent to selective etching, the samples were flushed with deionized water and blown dry with nitrogen. Electrical shorts were experienced despite the SEM inspection, indicating the presence of a gap.

AB - The fabrication of planar nanogap electrodes on a silicon substrate, using direct high-resolution metal nanotransfer printing (nTP) was investigated. Molecular beam epitaxy (MBE) molds were obtained by growing a single-crystalline AlGaAs layer of micrometer thickness on top of a GaAs substrate wafer, followed by either a single, thick GaAs layer or by a sequence of alternating GaAs and AlGaAs layers, followed by a second, micrometer-thick AlGaAs layer. All these mentioned layers were separated by 100-nm-wide support structures of the opposite material. Single-line molds were fabricated from a heterostructure comprising two 2-p.m-thick AlGaAs planes on either side of a buried 10-nm-thick GaAs layer. Subsequent to selective etching, the samples were flushed with deionized water and blown dry with nitrogen. Electrical shorts were experienced despite the SEM inspection, indicating the presence of a gap.

KW - Heterostructures

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Planar nanogap electrodes by direct nanotransfer printing

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Keywords

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