Quantum transport in graphene nanoribbons: Effects of edge reconstruction and chemical reactivity

Dubois S.M.-M.; Lopez-Bezanilla A.; Cresti A.; Triozon F.; Biel B.; Charlier J.-C.; Roche S.

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Quantum transport in graphene nanoribbons: Effects of edge reconstruction and chemical reactivity

机译：石墨烯纳米带中的量子传输：边缘重建和化学反应性的影响

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We present first-principles transport calculations of graphene nanoribbons with chemically reconstructed edge profiles. Depending on the geometry of the defect and the degree of hydrogenation, spectacularly different transport mechanisms are obtained. In the case of monohydrogenated pentagon (heptagon) defects, an effective acceptor (donor) character results in strong electron-hole conductance asymmetry. In contrast, weak backscattering is obtained for defects that preserve the benzenoid structure of graphene. Based on a tight-binding model derived from ab initio calculations, evidence for large conductance scaling fluctuations are found in disordered ribbons with lengths up to the micrometer scale.

机译：我们提出了具有化学重建边缘轮廓的石墨烯纳米带的第一性原理运输计算。根据缺陷的几何形状和氢化程度，获得了截然不同的传输机制。在单氢化五边形（七边形）缺陷的情况下，有效的受体（供体）特征会导致强烈的电子-空穴电导不对称性。相反，对于保留石墨烯的苯类结构的缺陷，获得了较弱的反向散射。基于从头算计算得出的紧密绑定模型，在无序色带中发现了大的电导比例缩放波动的证据，其长度高达微米级。

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《ACS nano》 |2010年第4期|共6页
作者
Dubois S.M.-M.; Lopez-Bezanilla A.; Cresti A.; Triozon F.; Biel B.; Charlier J.-C.; Roche S.;
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正文语种 eng
中图分类分子物理学、原子物理学;
关键词
Density-of-state; Edge reactivity; Graphene nanoribbons; Quantum transport;

机译：状态密度;边缘反应性;石墨烯纳米带;量子传输;

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专利

1. Quantum transport in graphene nanoribbons: Effects of edge reconstruction and chemical reactivity [J] . Dubois S.M.-M., Lopez-Bezanilla A., Cresti A., ACS nano . 2010,第4期

机译：石墨烯纳米带中的量子传输：边缘重建和化学反应性的影响
2. Computational Study of Edge Configuration and Quantum Confinement Effects on Graphene Nanoribbon Transport [J] . Sako R., Hosokawa H., Tsuchiya H. Electron Device Letters, IEEE . 2011,第1期

机译：石墨烯纳米带传输的边缘构型和量子限制效应的计算研究
3. Edge effects on quantum thermal transport in graphene nanoribbons: Tight-binding calculations [J] . Jinghua Lan, Jian-Sheng Wang, Chee Kwan Gan, Physical review . 2009,第11期

机译：石墨烯纳米带中量子热传输的边缘效应：紧密结合计算
4. Quantum Transport of Edge States in Zigzag Graphene NanoRibbon in the Presence of an Abrupt Structure Change due to Missing Atoms [C] . Nazmul Amin, Mahbub Alam IEEE Region 10 Conference . 2020

机译：Zigzag石墨烯纳米中边缘状态的量子传输在存在由于缺失的原子引起的突然结构变化中
5. Carrier transport in graphene, graphene nanoribbon and gallium nitride HEMTs. [D] . Fang, Tian. 2012

机译：石墨烯，石墨烯纳米带和氮化镓HEMT中的载流子传输。
6. Data for quantum phonon transport in strained carbon atomic chains bridging graphene and graphene nanoribbon electrodes [O] . Hu Sung Kim, Tae Hyung Kim, Yong-Hoon Kim 2018

机译：桥接石墨烯和石墨烯纳米带电极的应变碳原子链中量子声子传输的数据
7. Quantum Transport in Graphene Nanoribbons: Effects of Edge Reconstruction and Chemical Reactivity [O] . Simon M. -m. Dubois, Ro Lopez-bezanilla, Ro Cresti, 2014

机译：石墨烯纳米带中的量子输运：边缘重建和化学反应性的影响

Quantum transport in graphene nanoribbons: Effects of edge reconstruction and chemical reactivity

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