通过应变调节碳纳米管的带隙。

Tuning carbon nanotube band gaps with strain.

作者信息

Minot E D, Yaish Yuval, Sazonova Vera, Park Ji-Yong, Brink Markus, McEuen Paul L

机构信息

Laboratory of Atomic and Solid-State Physics, Cornell University, Ithaca, NY 14853, USA.

出版信息

Phys Rev Lett. 2003 Apr 18;90(15):156401. doi: 10.1103/PhysRevLett.90.156401. Epub 2003 Apr 15.

DOI:10.1103/PhysRevLett.90.156401

PMID:12732057

Abstract

We show that the band structure of a carbon nanotube (NT) can be dramatically altered by mechanical strain. We employ an atomic force microscope tip to simultaneously vary the NT strain and to electrostatically gate the tube. We show that strain can open a band gap in a metallic NT and modify the band gap in a semiconducting NT. Theoretical work predicts that band gap changes can range between +/-100 meV per 1% stretch, depending on NT chirality, and our measurements are consistent with this predicted range.

摘要

我们表明，碳纳米管（NT）的能带结构会因机械应变而发生显著改变。我们使用原子力显微镜探针同时改变纳米管的应变并对其进行静电栅控。我们表明，应变可以在金属性纳米管中打开一个带隙，并改变半导体性纳米管中的带隙。理论研究预测，根据纳米管的手性，每1%的拉伸，带隙变化范围可达±100毫电子伏特，我们的测量结果与这一预测范围相符。

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通过应变调节碳纳米管的带隙。

Tuning carbon nanotube band gaps with strain.

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