The Effects of Dangling Bonds on AlN Nanoribbons: A First-Principles Study

Ting ting Sun; Yong xin Wang; Zheng Chen; Xiu juan Du

doi:10.1007/s10948-014-2858-8

The Effects of Dangling Bonds on AlN Nanoribbons: A First-Principles Study

Ting ting Sun, Yong xin Wang, Zheng Chen, Xiu juan Du

Queen Mary University of London Engineering School

Northwestern Polytechnical University Xian

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

1 Scopus citations

Abstract

The effects of dangling bonds on electronic and magnetic properties for both zigzag AlN nanoribbons (ZAlNNRs) and armchair AlN nanoribbons (AAlNNRs) are studied by using first-principles calculations. Though ZAlNNRs or AAlNNRs terminated with H at both edges are nonmagnetic semiconductors, the results show that no H at the left side and no H at both edges cause magnetic metal for ZAlNNRs, but magnetic semimetal for ZAlNNRs with no H terminated at the right side, which open a way to design magnetic nanodevices based on AlNNRs. The AAlNNRs with unilateral hydrogen passivation or no H at both edges are still nonmagnetic semiconductors. ZAlNNRs with no H at the right side have a spin polarization value of 100 %, indicating these systems can be used to construct efficient spin-polarized transport devices.

Original language	English
Pages (from-to)	271-275
Number of pages	5
Journal	Journal of Superconductivity and Novel Magnetism
Volume	28
Issue number	1
DOIs	https://doi.org/10.1007/s10948-014-2858-8
State	Published - Jan 2014

Keywords

AlN nanoribbons
Electronic
First principles
Magnetic

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10.1007/s10948-014-2858-8

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title = "The Effects of Dangling Bonds on AlN Nanoribbons: A First-Principles Study",

abstract = "The effects of dangling bonds on electronic and magnetic properties for both zigzag AlN nanoribbons (ZAlNNRs) and armchair AlN nanoribbons (AAlNNRs) are studied by using first-principles calculations. Though ZAlNNRs or AAlNNRs terminated with H at both edges are nonmagnetic semiconductors, the results show that no H at the left side and no H at both edges cause magnetic metal for ZAlNNRs, but magnetic semimetal for ZAlNNRs with no H terminated at the right side, which open a way to design magnetic nanodevices based on AlNNRs. The AAlNNRs with unilateral hydrogen passivation or no H at both edges are still nonmagnetic semiconductors. ZAlNNRs with no H at the right side have a spin polarization value of 100 %, indicating these systems can be used to construct efficient spin-polarized transport devices.",

keywords = "AlN nanoribbons, Electronic, First principles, Magnetic",

author = "Sun, {Ting ting} and Wang, {Yong xin} and Zheng Chen and Du, {Xiu juan}",

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doi = "10.1007/s10948-014-2858-8",

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AU - Chen, Zheng

AU - Du, Xiu juan

PY - 2014/1

Y1 - 2014/1

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AB - The effects of dangling bonds on electronic and magnetic properties for both zigzag AlN nanoribbons (ZAlNNRs) and armchair AlN nanoribbons (AAlNNRs) are studied by using first-principles calculations. Though ZAlNNRs or AAlNNRs terminated with H at both edges are nonmagnetic semiconductors, the results show that no H at the left side and no H at both edges cause magnetic metal for ZAlNNRs, but magnetic semimetal for ZAlNNRs with no H terminated at the right side, which open a way to design magnetic nanodevices based on AlNNRs. The AAlNNRs with unilateral hydrogen passivation or no H at both edges are still nonmagnetic semiconductors. ZAlNNRs with no H at the right side have a spin polarization value of 100 %, indicating these systems can be used to construct efficient spin-polarized transport devices.

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The Effects of Dangling Bonds on AlN Nanoribbons: A First-Principles Study

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Keywords

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