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使用 CdSe 量子点阵列种籽层在石墨烯上均匀生长高质量的氧化物薄膜。

Uniform growth of high-quality oxide thin films on graphene using a CdSe quantum dot array seeding layer.

机构信息

SKKU Advanced Institute of Nanotechnology (SAINT), Sungkyunkwan University , Suwon 440-746, Korea.

出版信息

ACS Appl Mater Interfaces. 2014 Aug 13;6(15):13015-22. doi: 10.1021/am502922w. Epub 2014 Aug 1.

Abstract

Graphene displays outstanding properties as an electrode and a semiconducting channel material for transistors; however, the weak interfacial bond between graphene and an inorganic oxide material-based insulator presents a major constraint on these applications. Here, we report a new approach to improving the interface between the two materials using a CdSe quantum dot (QD)-based seeding layer in an inorganic material-graphene junction. CdSe QDs were electrochemically grown on graphene without degrading the properties of the graphene layer. The graphene structure was then used as the electrode in an oxide semiconductor by depositing a zinc oxide thin film onto the graphene coated with a QD seed layer (QD/G). The zinc oxide film adhered strongly to the graphene layer and provided a low contact resistance. A high-k dielectric layer in the form of an HfO2 film, which is an essential element in the fabrication of high-performance graphene-based field effect transistors, was also uniformly formed on the QD/G sheet using atomic layer deposition. The resulting transistors provided a relatively good performance, yielding hole and electron mobilities of 2600 and 2000 cm(2)/V·s.

摘要

石墨烯作为电极和晶体管的半导体沟道材料具有优异的性能;然而,石墨烯与基于无机氧化物材料的绝缘体之间较弱的界面键合极大地限制了这些应用。在这里,我们报告了一种使用基于 CdSe 量子点 (QD) 的种晶层来改善两种材料之间界面的新方法,在无机材料-石墨烯结中。CdSe QD 无需降解石墨烯层即可在石墨烯上电生长。然后,通过在涂有 QD 种晶层的石墨烯上沉积氧化锌薄膜,将石墨烯结构用作氧化物半导体的电极(QD/G)。氧化锌薄膜牢固地附着在石墨烯层上,并提供了低接触电阻。使用原子层沉积,在 QD/G 片上还均匀地形成了高介电常数的 HfO2 薄膜形式的高 k 电介质层,这是制造高性能基于石墨烯的场效应晶体管的基本元素。所得到的晶体管提供了相对较好的性能,产生了 2600 和 2000 cm2/V·s 的空穴和电子迁移率。

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