Coupling of electric field and bending modulated ballistic transport properties of copper nanowires

C. He; R. Y. Huang; Z. Q. Shi; W. X. Zhang

doi:10.1179/1753555714Y.0000000205

Coupling of electric field and bending modulated ballistic transport properties of copper nanowires

C. He
, R. Y. Huang
, Z. Q. Shi
, W. X. Zhang

School of Materials Science and Engineering

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

1 Scopus citations

Abstract

Coupling effect of electric field and bending on ballistic transport properties of copper nanowires (NWs) has been studied for the future application in solar cells and flexible displays. Our density function calculations show that when electric field strength V is equal to 0·5 V A°^-1, both structures (non-helical strand and helical strand) of CuNW are more stable and exhibit excellent quantum conductivity. Moreover, the helical structures have better stability than the non-helical ones since it owns higher collapse resistant f when V=1 V A°^-1. These results suggested that coupling of electric field and bending can be used to tune transport properties of CuNWs, which may be of help in the design of flexible nanodevices.

Original language	English
Pages (from-to)	A36-A40
Journal	Materials Technology
Volume	30
Issue number	A1
DOIs	https://doi.org/10.1179/1753555714Y.0000000205
State	Published - 1 Mar 2015

Keywords

Copper nanowires
Density functional theory
Electronic properties
Transport properties

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10.1179/1753555714Y.0000000205

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title = "Coupling of electric field and bending modulated ballistic transport properties of copper nanowires",

abstract = "Coupling effect of electric field and bending on ballistic transport properties of copper nanowires (NWs) has been studied for the future application in solar cells and flexible displays. Our density function calculations show that when electric field strength V is equal to 0·5 V A°-1, both structures (non-helical strand and helical strand) of CuNW are more stable and exhibit excellent quantum conductivity. Moreover, the helical structures have better stability than the non-helical ones since it owns higher collapse resistant f when V=1 V A°-1. These results suggested that coupling of electric field and bending can be used to tune transport properties of CuNWs, which may be of help in the design of flexible nanodevices.",

keywords = "Copper nanowires, Density functional theory, Electronic properties, Transport properties",

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doi = "10.1179/1753555714Y.0000000205",

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T1 - Coupling of electric field and bending modulated ballistic transport properties of copper nanowires

AU - He, C.

AU - Huang, R. Y.

AU - Shi, Z. Q.

AU - Zhang, W. X.

PY - 2015/3/1

Y1 - 2015/3/1

N2 - Coupling effect of electric field and bending on ballistic transport properties of copper nanowires (NWs) has been studied for the future application in solar cells and flexible displays. Our density function calculations show that when electric field strength V is equal to 0·5 V A°-1, both structures (non-helical strand and helical strand) of CuNW are more stable and exhibit excellent quantum conductivity. Moreover, the helical structures have better stability than the non-helical ones since it owns higher collapse resistant f when V=1 V A°-1. These results suggested that coupling of electric field and bending can be used to tune transport properties of CuNWs, which may be of help in the design of flexible nanodevices.

AB - Coupling effect of electric field and bending on ballistic transport properties of copper nanowires (NWs) has been studied for the future application in solar cells and flexible displays. Our density function calculations show that when electric field strength V is equal to 0·5 V A°-1, both structures (non-helical strand and helical strand) of CuNW are more stable and exhibit excellent quantum conductivity. Moreover, the helical structures have better stability than the non-helical ones since it owns higher collapse resistant f when V=1 V A°-1. These results suggested that coupling of electric field and bending can be used to tune transport properties of CuNWs, which may be of help in the design of flexible nanodevices.

KW - Copper nanowires

KW - Density functional theory

KW - Electronic properties

KW - Transport properties

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DO - 10.1179/1753555714Y.0000000205

M3 - 文章

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VL - 30

SP - A36-A40

JO - Materials Technology

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ER -

Coupling of electric field and bending modulated ballistic transport properties of copper nanowires

Abstract

Keywords

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