A non-destructive n-doping method for graphene with precise control of electronic properties via atomic layer deposition

Graphene applications require high precision control of the Fermi level and carrier concentration via a nondestructive doping method. Here, we develop an effective n-doping technique using atomic layer deposition (ALD) of ZnO thin films on graphene through a reactive molecular layer. This ALD doping...

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Veröffentlicht in:	Nanoscale 2016-03, Vol.8 (9), p.5000-5005
Hauptverfasser:	Han, Kyu Seok, Kalode, Pranav Y, Koo Lee, Yong-Eun, Kim, Hongbum, Lee, Lynn, Sung, Myung Mo
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creator	Han, Kyu Seok Kalode, Pranav Y Koo Lee, Yong-Eun Kim, Hongbum Lee, Lynn Sung, Myung Mo
description	Graphene applications require high precision control of the Fermi level and carrier concentration via a nondestructive doping method. Here, we develop an effective n-doping technique using atomic layer deposition (ALD) of ZnO thin films on graphene through a reactive molecular layer. This ALD doping method is nondestructive, simple, and precise. The ZnO thin films on graphene are uniform, conformal, of good quality with a low density of pinholes, and finely tunable in thickness with 1 Å resolution. We demonstrate graphene transistor control in terms of the Dirac point, carrier density, and doping state as a function of the ZnO thickness. Moreover, ZnO functions as an effective thin-film barrier against air-borne water and oxygen on the graphene, resulting in extraordinary stability in air for graphene devices. ZnO ALD was also applied to other two-dimensional materials including MoS2 and WSe2, which substantially enhanced electron mobility.
doi_str_mv	10.1039/c5nr08016a
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title	A non-destructive n-doping method for graphene with precise control of electronic properties via atomic layer deposition
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