Silicon nanowire piezoresistance: Impact of surface crystallographic orientation

Tymon Barwicz; Levente Klein; Steven J. Koester; Hendrik Hamann

doi:10.1063/1.3463456

Silicon nanowire piezoresistance: Impact of surface crystallographic orientation

Tymon Barwicz, Levente Klein, Steven J. Koester, Hendrik Hamann

Electrical and Computer Engineering

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

35 Scopus citations

Abstract

We investigate piezoresistance in lithographically defined silicon nanowires of various cross-sectional aspect ratios. Both 〈 110 〉 - and 〈 100 〉 -oriented nanowires are investigated under 〈 110 〉 -oriented strain. The nanowire thickness is varied from 23 to 45 nm and the nanowire width is varied from 5 to 113 nm. Our data shows piezoresistance in silicon nanowires being a surface induced effect with {110} surfaces inducing a much larger piezoresistance than {100} surfaces. This is consistent with a higher density of surface states on {110} surfaces than on {100} surfaces. Our experimental findings support recent computational work pointing toward surface states being the source of giant piezoresistance in silicon nanowires.

Original language	English (US)
Article number	023110
Journal	Applied Physics Letters
Volume	97
Issue number	2
DOIs	https://doi.org/10.1063/1.3463456
State	Published - Jul 12 2010

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title = "Silicon nanowire piezoresistance: Impact of surface crystallographic orientation",

abstract = "We investigate piezoresistance in lithographically defined silicon nanowires of various cross-sectional aspect ratios. Both 〈 110 〉 - and 〈 100 〉 -oriented nanowires are investigated under 〈 110 〉 -oriented strain. The nanowire thickness is varied from 23 to 45 nm and the nanowire width is varied from 5 to 113 nm. Our data shows piezoresistance in silicon nanowires being a surface induced effect with {110} surfaces inducing a much larger piezoresistance than {100} surfaces. This is consistent with a higher density of surface states on {110} surfaces than on {100} surfaces. Our experimental findings support recent computational work pointing toward surface states being the source of giant piezoresistance in silicon nanowires.",

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AU - Barwicz, Tymon

AU - Klein, Levente

AU - Koester, Steven J.

AU - Hamann, Hendrik

PY - 2010/7/12

Y1 - 2010/7/12

N2 - We investigate piezoresistance in lithographically defined silicon nanowires of various cross-sectional aspect ratios. Both 〈 110 〉 - and 〈 100 〉 -oriented nanowires are investigated under 〈 110 〉 -oriented strain. The nanowire thickness is varied from 23 to 45 nm and the nanowire width is varied from 5 to 113 nm. Our data shows piezoresistance in silicon nanowires being a surface induced effect with {110} surfaces inducing a much larger piezoresistance than {100} surfaces. This is consistent with a higher density of surface states on {110} surfaces than on {100} surfaces. Our experimental findings support recent computational work pointing toward surface states being the source of giant piezoresistance in silicon nanowires.

AB - We investigate piezoresistance in lithographically defined silicon nanowires of various cross-sectional aspect ratios. Both 〈 110 〉 - and 〈 100 〉 -oriented nanowires are investigated under 〈 110 〉 -oriented strain. The nanowire thickness is varied from 23 to 45 nm and the nanowire width is varied from 5 to 113 nm. Our data shows piezoresistance in silicon nanowires being a surface induced effect with {110} surfaces inducing a much larger piezoresistance than {100} surfaces. This is consistent with a higher density of surface states on {110} surfaces than on {100} surfaces. Our experimental findings support recent computational work pointing toward surface states being the source of giant piezoresistance in silicon nanowires.

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