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Absolute control of chirality unnecessary for wide-narrow-wide graphene field effect transistor

机译：宽宽宽石墨烯场效应晶体管不需要对手性的绝对控制

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In contrast with carbon nanotubes, graphene nanoribbons (GNRs) suffer from edge roughness that dilutes its chirality dependence, creating a single inverse power law curve relating energy-bandgap and width. Thus all narrow nanoribbons (>10nm) are semiconducting while all wide nanoribbons are metallic. Our model which combines well-benchmarked semi-empirical Extended Huckel Theory (EHT)based electronic structure with an atomistic theory for quantum transport to illustrate this dilution of chirality dependence not-predicted by simplified tight-binding theory with ideal GNRs, but observed in experiments.

机译：与碳纳米管相比，石墨烯纳米杆（GNRS）遭受边缘粗糙度，其稀释其性行为依赖性，从而产生具有能量带隙和宽度的单一反向动力法曲线。因此，所有窄的纳米波巴（> 10nm）都是半导体，而所有宽纳米都是金属的。我们的模型，将基于基于基于基于基于基于基于基准的半经验延伸的Huckel理论（EHT）的模型，具有用于量子传输的原子理论，以说明通过理想的GNRS简化的紧密结合理论而未预测的这种手性依赖性的稀释性，但在实验中观察到。

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《Device Research Conference》|2009年||共2页
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中图分类 TP23-53;
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carbon nanotubes; chirality; field effect transistors; graphene; atomistic theory; chirality absolute control; chirality dependence; edge roughness; electronic structure; energy bandgap; graphene nanoribbons; inverse power law curve; quantum transport; semi-empirical extended Huckel theory; tight-binding theory; wide-narrow-wide graphene field effect transistor;

机译：碳纳米管;手性;场效应晶体管;石墨烯;原子理论;手性绝对控制;手性依赖;边缘粗糙;电子结构;量子传输;半经验延伸的哈奇理论;紧密束缚理论;宽宽阔的石墨烯场效应晶体管;

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1. Controlling the Dirac point voltage of graphene by mechanically bending the ferroelectric gate of a graphene field effect transistor [J] . Hu Guangliang, Wu Jingying, Ma Chunrui, Materials Horizons . 2019,第2期

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2. Physical Modeling of Gate-Controlled Schottky Barrier Lowering of Metal-Graphene Contacts in Top-Gated Graphene Field-Effect Transistors [J] . Ling-Feng Mao, Huansheng Ning, Zong-Liang Huo, Scientific reports. . 2015,第1期

机译：顶部栅极石墨烯场效应晶体管中金属石墨烯触点的栅极控制肖特基势垒降低的物理模型
3. Fabrication of Graphene Field-effect Transistor with Field Controlling Electrodes to improve f(T) [J] . Al-Amin C., Karabiyik M., Pala N. Microelectronic Engineering . 2016,第octa期

机译：利用场控制电极制备石墨烯场效应晶体管以改善f（T）
4. Absolute control of chirality unnecessary for wide-narrow-wide graphene field effect transistor [C] . Tseng F., Unluer D., Stan M., Device Research Conference: Conference Digest . 2009

机译：宽窄宽石墨烯场效应晶体管无需完全控制手性
5. Fundamental Studies of Supported Graphene Interfaces: Defect Density of States in Graphene Field Effect Transistors (FETs) and Ideal Graphene - Silicon Schottky Diodes [D] . Sinha, Dhiraj P. 2014

机译：支持石墨烯界面的基本研究：石墨烯场效应晶体管（FET）中缺陷密度和理想石墨烯 - 硅肖丝狄克二极管
6. Physical Modeling of Gate-Controlled Schottky Barrier Lowering of Metal-Graphene Contacts in Top-Gated Graphene Field-Effect Transistors [O] . Ling-Feng Mao, Huansheng Ning, Zong-Liang Huo, -1

机译：顶部栅极石墨烯场效应晶体管中金属石墨烯触点的栅极控制肖特基势垒降低的物理模型
7. Physical Modeling of Gate-Controlled Schottky Barrier Lowering of Metal-Graphene Contacts in Top-Gated Graphene Field-Effect Transistors [O] . Ling-Feng Mao, Huansheng Ning, Zong-Liang Huo, 2015

机译：顶门石墨烯场效应晶体管金属 - 石墨烯接触栅极控制肖特基屏障的物理建模
8. New Route toward Systematic Control of Electronic Structures of Graphene and Fabrication of Graphene Field Effect Transistors. [R] . Pala, N. 2016

机译：石墨烯电子结构系统控制的新途径及石墨烯场效应晶体管的制备。

Absolute control of chirality unnecessary for wide-narrow-wide graphene field effect transistor

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