A proposed confinement modulated gap nanowire transistor based on a metal (Tin)

Lida Ansari; Giorgos Fagas; Jean Pierre Colinge; James C. Greer

doi:10.1021/nl2040817

A proposed confinement modulated gap nanowire transistor based on a metal (Tin)

Lida Ansari, Giorgos Fagas, Jean Pierre Colinge, James C. Greer

Research output: Journal Publication › Article › peer-review

45 Citations (Scopus)

Abstract

Energy bandgaps are observed to increase with decreasing diameter due to quantum confinement in quasi-one-dimensional semiconductor nanostructures or nanowires. A similar effect is observed in semimetal nanowires for sufficiently small wire diameters: A bandgap is induced, and the semimetal nanowire becomes a semiconductor. We demonstrate that on the length scale on which the semimetal-semiconductor transition occurs, this enables the use of bandgap engineering to form a field-effect transistor near atomic dimensions and eliminates the need for doping in the transistor's source, channel, or drain. By removing the requirement to supply free carriers by introducing dopant impurities, quantum confinement allows for a materials engineering to overcome the primary obstacle to fabricating sub-5 nm transistors, enabling aggressive scaling to near atomic limits.

Original language	English
Pages (from-to)	2222-2227
Number of pages	6
Journal	Nano Letters
Volume	12
Issue number	5
DOIs	https://doi.org/10.1021/nl2040817
Publication status	Published - 9 May 2012
Externally published	Yes

Keywords

Ab initio calculations
electron transport
electronic structure
gray tin
nanowire transistor
quantum confinement

ASJC Scopus subject areas

Bioengineering
General Chemistry
General Materials Science
Condensed Matter Physics
Mechanical Engineering

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10.1021/nl2040817

Cite this

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abstract = "Energy bandgaps are observed to increase with decreasing diameter due to quantum confinement in quasi-one-dimensional semiconductor nanostructures or nanowires. A similar effect is observed in semimetal nanowires for sufficiently small wire diameters: A bandgap is induced, and the semimetal nanowire becomes a semiconductor. We demonstrate that on the length scale on which the semimetal-semiconductor transition occurs, this enables the use of bandgap engineering to form a field-effect transistor near atomic dimensions and eliminates the need for doping in the transistor's source, channel, or drain. By removing the requirement to supply free carriers by introducing dopant impurities, quantum confinement allows for a materials engineering to overcome the primary obstacle to fabricating sub-5 nm transistors, enabling aggressive scaling to near atomic limits.",

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AU - Ansari, Lida

AU - Fagas, Giorgos

AU - Colinge, Jean Pierre

AU - Greer, James C.

PY - 2012/5/9

Y1 - 2012/5/9

N2 - Energy bandgaps are observed to increase with decreasing diameter due to quantum confinement in quasi-one-dimensional semiconductor nanostructures or nanowires. A similar effect is observed in semimetal nanowires for sufficiently small wire diameters: A bandgap is induced, and the semimetal nanowire becomes a semiconductor. We demonstrate that on the length scale on which the semimetal-semiconductor transition occurs, this enables the use of bandgap engineering to form a field-effect transistor near atomic dimensions and eliminates the need for doping in the transistor's source, channel, or drain. By removing the requirement to supply free carriers by introducing dopant impurities, quantum confinement allows for a materials engineering to overcome the primary obstacle to fabricating sub-5 nm transistors, enabling aggressive scaling to near atomic limits.

AB - Energy bandgaps are observed to increase with decreasing diameter due to quantum confinement in quasi-one-dimensional semiconductor nanostructures or nanowires. A similar effect is observed in semimetal nanowires for sufficiently small wire diameters: A bandgap is induced, and the semimetal nanowire becomes a semiconductor. We demonstrate that on the length scale on which the semimetal-semiconductor transition occurs, this enables the use of bandgap engineering to form a field-effect transistor near atomic dimensions and eliminates the need for doping in the transistor's source, channel, or drain. By removing the requirement to supply free carriers by introducing dopant impurities, quantum confinement allows for a materials engineering to overcome the primary obstacle to fabricating sub-5 nm transistors, enabling aggressive scaling to near atomic limits.

KW - Ab initio calculations

KW - electron transport

KW - electronic structure

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KW - nanowire transistor

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A proposed confinement modulated gap nanowire transistor based on a metal (Tin)

Abstract

Keywords

ASJC Scopus subject areas

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