G. Xu, J. Bai, C. Torres, E. B. Song, J. Tang, Yanlin Zhou, X. Duan, Y. Zhang, Y. Huang, K. Wang
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引用次数: 2
摘要
石墨烯纳米带(GNR)是一种准一维薄膜,通过量子约束和/或局域化效应存在带隙。与块体石墨烯相比,GNR在实现高离子/电离比方面具有很高的潜力。然而,由于不可控的边缘粗糙度和/或状态,GNR的载流子迁移率表现出强烈的退化。大多数报道的gnr - fet使用电子束光刻工艺进行图像化,其中电子束的光斑大小限制了边缘的光滑性1。在这项工作中,我们提出了一种基于纳米线掩膜的GNR制造方法,其中边缘粗糙度由纳米线的表面粗糙度决定(2)。采用四端测量装置,单层纳米带(SLR)器件在300K时显示μ空穴~ 1180cm2/(Vs),离子/ off >7,低频噪声图A ~ 10−6。此外,短通道SLR (~ 250nm)在77K3处显示出电导量子化,并证实了通过这种方法可以实现准弹道输运性质。
Nanowire-mask based fabrication of high mobility and low noise graphene nanoribbon short-channel field-effect transistors
Graphene nanoribbon (GNR) is a quasi one-dimensional film, in which a bandgap exists through the quantum confinement and/or localization effect. Compared to bulk graphene, GNR has high potential in achieving high Ion/Ioff ratio. The carrier mobility of GNR, however, exhibits strong degradation because of the uncontrollable edge roughness and/or states. Most reported GNR-FETs are patterned using ebeam-lithography processes, where the spot size of the electron beam limits the edge smoothness1. In this work, we present a GNR fabrication method based on a nanowire-mask, where the edge roughness is determined by the surface roughness of the nanowire (<1nm) 2. With four-terminal measurement setup, single layer nanoribbon (SLR) devices show μhole∼1180cm2/(Vs), Ion/Ioff >7 and low frequency noise figure A∼10−6 at 300K. Moreover, short-channel SLR (∼250nm) shows conductance quantization at 77K3, and confirms that the quasi-ballistic transport properties can be achieved through this method.
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