Silicon nanowire band gap modification

Michael Nolan; Sean O'Callaghan; Giorgos Fagas; James C. Greer; Thomas Frauenheim

doi:10.1021/nl061888d

Silicon nanowire band gap modification

Michael Nolan
, Sean O'Callaghan
, Giorgos Fagas
, James C. Greer
, Thomas Frauenheim

University College Cork
University of Bremen

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

Abstract

Band gap modification for small-diameter (∼1 nm) silicon nanowires resulting from the use of different species for surface termination is investigated by density functional theory calculations. Because of quantum confinement, small-diameter wires exhibit a direct band gap that increases as the wire diameter narrows, irrespective of surface termination. This effect has been observed in previous experimental and theoretical studies for hydrogenated wires. For a fixed cross-section, the functional group used to saturate the silicon surface significantly modifies the band gap, resulting in relative energy shifts of up to an electronvolt. The band gap shifts are traced to details of the hybridization between the silicon valence band and the frontier orbitals of the terminating group, which is in competition with quantum confinement.

Original language	English
Pages (from-to)	34-38
Number of pages	5
Journal	Nano Letters
Volume	7
Issue number	1
DOIs	https://doi.org/10.1021/nl061888d
Publication status	Published - Jan 2007

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10.1021/nl061888d

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title = "Silicon nanowire band gap modification",

abstract = "Band gap modification for small-diameter (∼1 nm) silicon nanowires resulting from the use of different species for surface termination is investigated by density functional theory calculations. Because of quantum confinement, small-diameter wires exhibit a direct band gap that increases as the wire diameter narrows, irrespective of surface termination. This effect has been observed in previous experimental and theoretical studies for hydrogenated wires. For a fixed cross-section, the functional group used to saturate the silicon surface significantly modifies the band gap, resulting in relative energy shifts of up to an electronvolt. The band gap shifts are traced to details of the hybridization between the silicon valence band and the frontier orbitals of the terminating group, which is in competition with quantum confinement.",

author = "Michael Nolan and Sean O'Callaghan and Giorgos Fagas and Greer, \{James C.\} and Thomas Frauenheim",

year = "2007",

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doi = "10.1021/nl061888d",

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journal = "Nano Letters",

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AU - Nolan, Michael

AU - O'Callaghan, Sean

AU - Fagas, Giorgos

AU - Greer, James C.

AU - Frauenheim, Thomas

PY - 2007/1

Y1 - 2007/1

N2 - Band gap modification for small-diameter (∼1 nm) silicon nanowires resulting from the use of different species for surface termination is investigated by density functional theory calculations. Because of quantum confinement, small-diameter wires exhibit a direct band gap that increases as the wire diameter narrows, irrespective of surface termination. This effect has been observed in previous experimental and theoretical studies for hydrogenated wires. For a fixed cross-section, the functional group used to saturate the silicon surface significantly modifies the band gap, resulting in relative energy shifts of up to an electronvolt. The band gap shifts are traced to details of the hybridization between the silicon valence band and the frontier orbitals of the terminating group, which is in competition with quantum confinement.

AB - Band gap modification for small-diameter (∼1 nm) silicon nanowires resulting from the use of different species for surface termination is investigated by density functional theory calculations. Because of quantum confinement, small-diameter wires exhibit a direct band gap that increases as the wire diameter narrows, irrespective of surface termination. This effect has been observed in previous experimental and theoretical studies for hydrogenated wires. For a fixed cross-section, the functional group used to saturate the silicon surface significantly modifies the band gap, resulting in relative energy shifts of up to an electronvolt. The band gap shifts are traced to details of the hybridization between the silicon valence band and the frontier orbitals of the terminating group, which is in competition with quantum confinement.

UR - https://www.scopus.com/pages/publications/33846882606

U2 - 10.1021/nl061888d

DO - 10.1021/nl061888d

M3 - Article

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SN - 1530-6984

VL - 7

SP - 34

EP - 38

JO - Nano Letters

JF - Nano Letters

IS - 1

ER -

Silicon nanowire band gap modification

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