Nanoscale reduction of graphene fluoride via thermochemical nanolithography

Lee W.-K.; Haydell M.; Robinson J.T.; Laracuente A.R.; Cimpoiasu E.; King W.P.; Sheehan P.E.

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Nanoscale reduction of graphene fluoride via thermochemical nanolithography

机译：通过热化学纳米光刻技术对氟化石墨烯进行纳米级还原

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Graphene nanoribbons (GNRs) would be the ideal building blocks for all carbon electronics; however, many challenges remain in developing an appropriate nanolithography that generates high-quality ribbons in registry with other devices. Here we report direct and local fabrication of GNRs by thermochemical nanolithography, which uses a heated AFM probe to locally convert highly insulating graphene fluoride to conductive graphene. Chemically isolated GNRs as narrow as 40 nm show p-doping behavior and sheet resistances as low as 22.9 KΩ/□ in air, only approximately 10× higher than that of pristine graphene. The impact of probe temperature and speed are examined as well as the variable-temperature transport properties of the GNR.

机译：石墨烯纳米带（GNR）将是所有碳电子产品的理想构建基块。然而，在开发合适的纳米光刻技术以与其他设备配准时产生高质量的色带方面，仍然存在许多挑战。在这里，我们报告了通过热化学纳米光刻技术直接和局部制造GNR的过程，该技术使用加热的AFM探针将高度绝缘的氟化石墨烯局部转化为导电石墨烯。化学隔离的GNR窄至40 nm，在空气中显示p掺杂行为，薄层电阻低至22.9KΩ/□，仅比原始石墨烯高约10倍。检查了探头温度和速度的影响以及GNR的可变温度传输特性。

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《ACS nano》 |2013年第7期|共6页
作者
Lee W.-K.; Haydell M.; Robinson J.T.; Laracuente A.R.; Cimpoiasu E.; King W.P.; Sheehan P.E.;
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正文语种 eng
中图分类 53.8;
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atomic force microscopy; graphene fluoride; graphene nanoribbons; thermochemical nanolithography;

机译：原子力显微镜氟化石墨烯石墨烯纳米带热化学纳米光刻;

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1. Nanoscale reduction of graphene fluoride via thermochemical nanolithography [J] . Lee W.-K., Haydell M., Robinson J.T., ACS nano . 2013,第7期

机译：通过热化学纳米光刻技术对氟化石墨烯进行纳米级还原
2. Fabricating nanoscale chemical gradients with thermoChemical nanoLithography [J] . Carroll K.M., Giordano A.J., Wang D., Langmuir: The ACS Journal of Surfaces and Colloids . 2013,第27期

机译：使用热化学纳米光刻技术制造纳米级化学梯度
3. Nanoscale Fabrication of the Ferroelectric Polymer Poly(vinylidene Fluoride with Trifluoroethylene) P(VDF-TrFE) 75:25 Thin Films by Atomic Force Microscope Nanolithography [J] . Omar Vega, David Delgado, Freddy Wong, Scanning . 2012,第6期

机译：原子力显微镜纳米光刻技术制备铁电聚合物聚偏氟乙烯与三氟乙烯P（VDF-TrFE）75:25薄膜
4. Reversible Nanoscale Local Wettability Modifications by Thermochemical Nanolithography [C] . Debin Wang, Takashi Okada, Robert Szoszkiewicz, Symposium on Nanoscale Pattern Formation . 2008

机译：热化学纳米光刻可逆纳米级局部润湿性修饰
5. Thermochemical nanolithography fabrication and atomic force microscopy characterization of functional nanostructures. [D] . Wang, Debin. 2010

机译：功能纳米结构的热化学纳米光刻制造和原子力显微镜表征。
6. Nanoscale Fabrication of the Ferroelectric Polymer Poly(vinylidene Fluoride with Trifluoroethylene) P(VDF-TrFE) 75:25 Thin Films by Atomic Force Microscope Nanolithography [O] . Omar Vega, David Delgado, Freddy Wong, -1

机译：纳米级制造铁电聚合物聚（偏二氟乙烯与三氟乙烯）P（VDF-TRFE）75:25通过原子力显微镜纳米线薄膜
7. Nanoscale Tunable Reduction of Graphene Oxide for Graphene Electronics [O] . Z. Wei, R. Marder, C. Berger, 2015

机译：用于石墨烯电子的纳米级可调节氧化石墨烯的还原
8. Feasibility Study of Nanoscale Semiconductor Manufacture Using Thermal Dip Pen Nanolithography [R] . King, W. P. 2006

机译：利用热浸笔纳米光刻技术制备纳米半导体的可行性研究

Nanoscale reduction of graphene fluoride via thermochemical nanolithography

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