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The complex band structure for armchair graphene nanoribbons 被引量:1

The complex band structure for armchair graphene nanoribbons
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摘要 Using a tight binding transfer matrix method, we calculate the complex band structure of armchair graphene nanoribbons. The real part of the complex band structure calculated by the transfer matrix method fits well with the bulk band structure calculated by a Hermitian matrix. The complex band structure gives extra information on carrier's decay behaviour. The imaginary loop connects the conduction and valence band, and can profoundly affect the characteristics of nanoscale electronic device made with graphene nanoribbons. In this work, the complex band structure calculation includes not only the first nearest neighbour interaction, but also the effects of edge bond relaxation and the third nearest neighbour interaction. The band gap is classified into three classes. Due to the edge bond relaxation and the third nearest neighbour interaction term, it opens a band gap for N = 3M- 1. The band gap is almost unchanged for N =3M + 1, but decreased for N = 3M. The maximum imaginary wave vector length provides additional information about the electrical characteristics of graphene nanoribbons, and is also classified into three classes. Using a tight binding transfer matrix method, we calculate the complex band structure of armchair graphene nanoribbons. The real part of the complex band structure calculated by the transfer matrix method fits well with the bulk band structure calculated by a Hermitian matrix. The complex band structure gives extra information on carrier's decay behaviour. The imaginary loop connects the conduction and valence band, and can profoundly affect the characteristics of nanoscale electronic device made with graphene nanoribbons. In this work, the complex band structure calculation includes not only the first nearest neighbour interaction, but also the effects of edge bond relaxation and the third nearest neighbour interaction. The band gap is classified into three classes. Due to the edge bond relaxation and the third nearest neighbour interaction term, it opens a band gap for N = 3M- 1. The band gap is almost unchanged for N =3M + 1, but decreased for N = 3M. The maximum imaginary wave vector length provides additional information about the electrical characteristics of graphene nanoribbons, and is also classified into three classes.
作者 张留军 夏同生
机构地区 School of Electronic Information Engineering
出处 《Chinese Physics B》 SCIE EI CAS CSCD 2010年第11期548-554,共7页 中国物理B(英文版)
基金 Project supported by the Fundamental Research Funds for the Central Universities (Grant No. YWF-10-02-040)
关键词 armchair graphene nanoribbons complex band structure edge bond relaxation third nearest neighbour interaction armchair graphene nanoribbons, complex band structure, edge bond relaxation, third nearest neighbour interaction
分类号 TB383.1 [一般工业技术—材料科学与工程]
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参考文献31

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同被引文献16

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引证文献1

Chinese Physics B
2010年 第11期

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