3D hyperbranched heterostructures of Ag nanocrystals-decorated ZnO nanopillars: Controlled growth and characterization of the optical properties

Herein, the synthesis along with the structural and optical characterization of 3D hyperbranched ZnO nanopillars (NPLs) decorated with Ag nanocrystals (NCs) is reported. This hyperbranched heterostructure, displaying broccoli-like morphology, was prepared via two-step synthesis method, in which free...

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Published in:CrystEngComm
Main Author: Daud S.N.H.; Haw C.Y.; Chiu W.S.; Aspanut Z.; Jani N.A.; Khiew P.S.; Lim Y.C.; Abd H.; Ali A.M.
Format: Article
Language:English
Published: Royal Society of Chemistry 2017
Online Access:https://www.scopus.com/inward/record.uri?eid=2-s2.0-85029944934&doi=10.1039%2fc7ce01159h&partnerID=40&md5=49882bee53a939685dd3afcd33067976
id 2-s2.0-85029944934
spelling 2-s2.0-85029944934
Daud S.N.H.; Haw C.Y.; Chiu W.S.; Aspanut Z.; Jani N.A.; Khiew P.S.; Lim Y.C.; Abd H.; Ali A.M.
3D hyperbranched heterostructures of Ag nanocrystals-decorated ZnO nanopillars: Controlled growth and characterization of the optical properties
2017
CrystEngComm
19
37
10.1039/c7ce01159h
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85029944934&doi=10.1039%2fc7ce01159h&partnerID=40&md5=49882bee53a939685dd3afcd33067976
Herein, the synthesis along with the structural and optical characterization of 3D hyperbranched ZnO nanopillars (NPLs) decorated with Ag nanocrystals (NCs) is reported. This hyperbranched heterostructure, displaying broccoli-like morphology, was prepared via two-step synthesis method, in which freestanding ZnO NPLs were hydrothermally grown onto a Zn foil substrate, followed by scrupulous decoration with Ag NCs using a similar approach. FESEM observations revealed that the reaction time highly influenced the crystallization mechanism, whereby the as-deposited Ag NCs could serve as a catalyst to induce secondary nucleation sites that promote the sprouting of secondary ZnO NPLs branches that grow along the edges of the upper half of the primary ZnO NPLs. HRTEM analysis was conducted to investigate the crystallography structure at the interfaces and elemental mapping was used to probe the elemental distribution. These results were further complemented with both XRD and Raman spectroscopy. Finally, diffuse reflectance and photoluminescence analysis were employed to elucidate the optical behaviour. A possible growth mechanism for obtaining such a unique broccoli-like morphology with a complicated nanoarchitecture is proposed. The present study could assist the development of a crystal engineering process for the preparation and analysis of hybrid nanostructures. © 2017 The Royal Society of Chemistry.
Royal Society of Chemistry
14668033
English
Article

author Daud S.N.H.; Haw C.Y.; Chiu W.S.; Aspanut Z.; Jani N.A.; Khiew P.S.; Lim Y.C.; Abd H.; Ali A.M.
spellingShingle Daud S.N.H.; Haw C.Y.; Chiu W.S.; Aspanut Z.; Jani N.A.; Khiew P.S.; Lim Y.C.; Abd H.; Ali A.M.
3D hyperbranched heterostructures of Ag nanocrystals-decorated ZnO nanopillars: Controlled growth and characterization of the optical properties
author_facet Daud S.N.H.; Haw C.Y.; Chiu W.S.; Aspanut Z.; Jani N.A.; Khiew P.S.; Lim Y.C.; Abd H.; Ali A.M.
author_sort Daud S.N.H.; Haw C.Y.; Chiu W.S.; Aspanut Z.; Jani N.A.; Khiew P.S.; Lim Y.C.; Abd H.; Ali A.M.
title 3D hyperbranched heterostructures of Ag nanocrystals-decorated ZnO nanopillars: Controlled growth and characterization of the optical properties
title_short 3D hyperbranched heterostructures of Ag nanocrystals-decorated ZnO nanopillars: Controlled growth and characterization of the optical properties
title_full 3D hyperbranched heterostructures of Ag nanocrystals-decorated ZnO nanopillars: Controlled growth and characterization of the optical properties
title_fullStr 3D hyperbranched heterostructures of Ag nanocrystals-decorated ZnO nanopillars: Controlled growth and characterization of the optical properties
title_full_unstemmed 3D hyperbranched heterostructures of Ag nanocrystals-decorated ZnO nanopillars: Controlled growth and characterization of the optical properties
title_sort 3D hyperbranched heterostructures of Ag nanocrystals-decorated ZnO nanopillars: Controlled growth and characterization of the optical properties
publishDate 2017
container_title CrystEngComm
container_volume 19
container_issue 37
doi_str_mv 10.1039/c7ce01159h
url https://www.scopus.com/inward/record.uri?eid=2-s2.0-85029944934&doi=10.1039%2fc7ce01159h&partnerID=40&md5=49882bee53a939685dd3afcd33067976
description Herein, the synthesis along with the structural and optical characterization of 3D hyperbranched ZnO nanopillars (NPLs) decorated with Ag nanocrystals (NCs) is reported. This hyperbranched heterostructure, displaying broccoli-like morphology, was prepared via two-step synthesis method, in which freestanding ZnO NPLs were hydrothermally grown onto a Zn foil substrate, followed by scrupulous decoration with Ag NCs using a similar approach. FESEM observations revealed that the reaction time highly influenced the crystallization mechanism, whereby the as-deposited Ag NCs could serve as a catalyst to induce secondary nucleation sites that promote the sprouting of secondary ZnO NPLs branches that grow along the edges of the upper half of the primary ZnO NPLs. HRTEM analysis was conducted to investigate the crystallography structure at the interfaces and elemental mapping was used to probe the elemental distribution. These results were further complemented with both XRD and Raman spectroscopy. Finally, diffuse reflectance and photoluminescence analysis were employed to elucidate the optical behaviour. A possible growth mechanism for obtaining such a unique broccoli-like morphology with a complicated nanoarchitecture is proposed. The present study could assist the development of a crystal engineering process for the preparation and analysis of hybrid nanostructures. © 2017 The Royal Society of Chemistry.
publisher Royal Society of Chemistry
issn 14668033
language English
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