通过模板法可扩展合成具有可控形态的少层石墨烯带及其在纳米机电开关中的应用。

Scalable synthesis of few-layer graphene ribbons with controlled morphologies by a template method and their applications in nanoelectromechanical switches.

作者信息

Wei Dacheng, Liu Yunqi, Zhang Hongliang, Huang Liping, Wu Bin, Chen Jianyi, Yu Gui

机构信息

Beijing National Laboratory for Molecular Sciences, Institute of Chemistry, Chinese Academy of Sciences, Beijing 100190, People's Republic of China.

出版信息

J Am Chem Soc. 2009 Aug 12;131(31):11147-54. doi: 10.1021/ja903092k.

DOI:10.1021/ja903092k

PMID:19618950

Abstract

Controllable and scalable production is of great importance for the application of graphene; however, to date, it is still a great challenge and a major obstacle which hampers its practical applications. Here, we develop a template chemical vapor deposition method for scalable synthesis of few-layer graphene ribbons (FLGRs) with controlled morphologies. The FLGRs have a good conductivity and are ideal for use in nanoelectromechanics (NEM). As an application, we fabricate a reversible NEM switch and a logic gate by using the FLGRs. This work realizes both controllable and scalable synthesis of graphene, provides an application of graphene in NEM switches, and would be valuable for both the scientific studies and the practical applications of graphene.

摘要

可控制且可扩展的生产对于石墨烯的应用至关重要；然而，迄今为止，这仍然是一个巨大的挑战和主要障碍，阻碍了其实际应用。在此，我们开发了一种模板化学气相沉积方法，用于可扩展地合成具有可控形态的少层石墨烯带（FLGRs）。这些FLGRs具有良好的导电性，非常适合用于纳米机电系统（NEM）。作为一项应用，我们使用FLGRs制造了一个可逆NEM开关和一个逻辑门。这项工作实现了石墨烯的可控且可扩展合成，提供了石墨烯在NEM开关中的应用，并且对于石墨烯的科学研究和实际应用都具有重要价值。

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Scalable synthesis of few-layer graphene ribbons with controlled morphologies by a template method and their applications in nanoelectromechanical switches.通过模板法可扩展合成具有可控形态的少层石墨烯带及其在纳米机电开关中的应用。

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通过模板法可扩展合成具有可控形态的少层石墨烯带及其在纳米机电开关中的应用。

Scalable synthesis of few-layer graphene ribbons with controlled morphologies by a template method and their applications in nanoelectromechanical switches.

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