Structurally Nanocrystalline-Electrically Single Crystalline ZnO-Reduced Graphene Oxide Composites

ZnO, a wide bandgap semiconductor, has attracted much attention due to its multifunctionality, such as transparent conducting oxide, light-emitting diode, photocatalyst, and so on. To improve its performances in the versatile applications, numerous hybrid strategies of ZnO with graphene have been at...

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Veröffentlicht in:	Nano letters 2014-09, Vol.14 (9), p.5104-5109
Hauptverfasser:	Nam, Woo Hyun, Kim, Bo Bae, Seo, Seul Gi, Lim, Young Soo, Kim, Jong-Young, Seo, Won-Seon, Choi, Won Kook, Park, Hyung-Ho, Lee, Jeong Yong
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creator	Nam, Woo Hyun Kim, Bo Bae Seo, Seul Gi Lim, Young Soo Kim, Jong-Young Seo, Won-Seon Choi, Won Kook Park, Hyung-Ho Lee, Jeong Yong
description	ZnO, a wide bandgap semiconductor, has attracted much attention due to its multifunctionality, such as transparent conducting oxide, light-emitting diode, photocatalyst, and so on. To improve its performances in the versatile applications, numerous hybrid strategies of ZnO with graphene have been attempted, and various synergistic effects have been achieved in the ZnO–graphene hybrid nanostructures. Here we report extraordinary charge transport behavior in Al-doped ZnO (AZO)-reduced graphene oxide (RGO) nanocomposites. Although the most challenging issue in semiconductor nanocomposites is their low mobilities, the AZO–RGO nanocomposites exhibit single crystal-like Hall mobility despite the large quantity of nanograin boundaries, which hinder the electron transport by the scattering with trapped charges. Because of the significantly weakened grain boundary barrier and the proper band alignment between the AZO and RGO, freely conducting electrons across the nanograin boundaries can be realized in the nanocomposites. This discovery of the structurally nanocrystalline-electrically single crystalline composite demonstrates a new route for enhancing the electrical properties in nanocomposites based on the hybrid strategy.
doi_str_mv	10.1021/nl5018089
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