Preserved conductance in covalently functionalized silicon nanowires

X. Blase; M. V. Fernández-Serra

doi:10.1103/PhysRevLett.100.046802

Preserved conductance in covalently functionalized silicon nanowires

X. Blase
, M. V. Fernández-Serra

Physics and Astronomy

Université de Lyon
Universite Claude Bernard Lyon 1
CNRS

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

26 Scopus citations

Abstract

We study by means of ab initio simulations the Landauer conductance of covalently functionalized silicon nanowires. We show that in the case of alkyl side chains, the most common linkers, silicon nanowires remain quasiballistic over a large energy range. More reactive side molecules, such as alkenyl or phenyl conjugated radicals, amino and alkoxide groups, are less favorable as they induce resonant backscattering in the valence bands mainly. Such results provide strong support for the use of selectively functionalized nanowires in (opto)electronic devices and molecular sensors.

Original language	English
Article number	046802
Journal	Physical Review Letters
Volume	100
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevLett.100.046802
State	Published - Jan 29 2008

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10.1103/PhysRevLett.100.046802

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title = "Preserved conductance in covalently functionalized silicon nanowires",

abstract = "We study by means of ab initio simulations the Landauer conductance of covalently functionalized silicon nanowires. We show that in the case of alkyl side chains, the most common linkers, silicon nanowires remain quasiballistic over a large energy range. More reactive side molecules, such as alkenyl or phenyl conjugated radicals, amino and alkoxide groups, are less favorable as they induce resonant backscattering in the valence bands mainly. Such results provide strong support for the use of selectively functionalized nanowires in (opto)electronic devices and molecular sensors.",

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AU - Fernández-Serra, M. V.

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N2 - We study by means of ab initio simulations the Landauer conductance of covalently functionalized silicon nanowires. We show that in the case of alkyl side chains, the most common linkers, silicon nanowires remain quasiballistic over a large energy range. More reactive side molecules, such as alkenyl or phenyl conjugated radicals, amino and alkoxide groups, are less favorable as they induce resonant backscattering in the valence bands mainly. Such results provide strong support for the use of selectively functionalized nanowires in (opto)electronic devices and molecular sensors.

AB - We study by means of ab initio simulations the Landauer conductance of covalently functionalized silicon nanowires. We show that in the case of alkyl side chains, the most common linkers, silicon nanowires remain quasiballistic over a large energy range. More reactive side molecules, such as alkenyl or phenyl conjugated radicals, amino and alkoxide groups, are less favorable as they induce resonant backscattering in the valence bands mainly. Such results provide strong support for the use of selectively functionalized nanowires in (opto)electronic devices and molecular sensors.

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U2 - 10.1103/PhysRevLett.100.046802

DO - 10.1103/PhysRevLett.100.046802

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Preserved conductance in covalently functionalized silicon nanowires

Abstract

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