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In situ growth, structure characterization, and enhanced photocatalysis of high-quality, single-crystalline ZnTe/ZnO branched nanoheterostructures

Single-crystalline, high-quality branched ZnTe-core/ZnO-branch nanoheterostructures were synthesized by an in situ strategy in an environmental scanning electron microscope. Composition and structure characterization confirmed that ZnO nanowires were perfectly epitaxially grown on ZnTe nanowires as...

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Published in:	Nanoscale 2011-01, Vol.3 (10), p.4418-4426
Main Authors:	Sun, Yanghui, Zhao, Qing, Gao, Jingyun, Ye, Yu, Wang, Wei, Zhu, Rui, Xu, Jun, Chen, Li, Yang, Jian, Dai, Lun, Liao, Zhi-Min, Yu, Dapeng
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Language:	English
Subjects:	Catalysis Crystallization Density Light Nanocomposites Nanomaterials Nanostructure Nanostructures - chemistry Nanowires Nanowires - chemistry Scanning electron microscopy Temperature Ultraviolet Rays Zinc oxide Zinc Oxide - chemistry Zinc tellurides
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container_title	Nanoscale
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creator	Sun, Yanghui Zhao, Qing Gao, Jingyun Ye, Yu Wang, Wei Zhu, Rui Xu, Jun Chen, Li Yang, Jian Dai, Lun Liao, Zhi-Min Yu, Dapeng
description	Single-crystalline, high-quality branched ZnTe-core/ZnO-branch nanoheterostructures were synthesized by an in situ strategy in an environmental scanning electron microscope. Composition and structure characterization confirmed that ZnO nanowires were perfectly epitaxially grown on ZnTe nanowires as branches. Noticeably, growth temperature plays a crucial role in determining the density and diameter of the ZnO nanobranches on ZnTe nanowires: a higher growth temperature leads to ZnO nanowires with higher density and smaller diameter. It was demonstrated that ZnO nanobranches exhibited a selective nucleation behavior on distinct side facets of ZnTe nanowires. Highly ordered ZnO nanobranches were found epitaxially grown on {211} facet of ZnTe nanowires, while there was no ZnO nanowire growth on {110} facet of ZnTe nanowires. Using first-principles calculation, we found that surface energy of distinct side facets has a strong impact on ZnO nucleation, and confirm that {211} facet of ZnTe nanowires is energetically more favorable for ZnO nanowire growth than {110} facet, which is in good agreement with our experimental findings. Remarkably, such unique ZnTe/ZnO 3D branched nanowire heterostructures exhibited improved photocatalytic abilities, superior to ZnO nanowires and ZnTe nanowires, due to the much enhanced effective surface area of their unique architecture and effective electron-hole separation at the ZnTe/ZnO interfaces.
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Composition and structure characterization confirmed that ZnO nanowires were perfectly epitaxially grown on ZnTe nanowires as branches. Noticeably, growth temperature plays a crucial role in determining the density and diameter of the ZnO nanobranches on ZnTe nanowires: a higher growth temperature leads to ZnO nanowires with higher density and smaller diameter. It was demonstrated that ZnO nanobranches exhibited a selective nucleation behavior on distinct side facets of ZnTe nanowires. Highly ordered ZnO nanobranches were found epitaxially grown on {211} facet of ZnTe nanowires, while there was no ZnO nanowire growth on {110} facet of ZnTe nanowires. Using first-principles calculation, we found that surface energy of distinct side facets has a strong impact on ZnO nucleation, and confirm that {211} facet of ZnTe nanowires is energetically more favorable for ZnO nanowire growth than {110} facet, which is in good agreement with our experimental findings. 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subjects	Catalysis Crystallization Density Light Nanocomposites Nanomaterials Nanostructure Nanostructures - chemistry Nanowires Nanowires - chemistry Scanning electron microscopy Temperature Ultraviolet Rays Zinc oxide Zinc Oxide - chemistry Zinc tellurides
title	In situ growth, structure characterization, and enhanced photocatalysis of high-quality, single-crystalline ZnTe/ZnO branched nanoheterostructures
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