Pure, Size Tunable ZnO Nanocrystals Assembled into Large Area PMMA Layer as Efficient Catalyst

Issraa Shahine,Patrice Miska,Safi Jradi,Aotmane En Naciri,El-Eulmi Bendeif,Hervé Rinnert,Suzanna Akil,Pierre Magri,Jean Jacques Gaumet,Nour Beydoun

doi:10.3390/catal9020162

Abstract

Here, we demonstrate for the first time a strategy to self-assemble ZnO nanoparticles (NP) on a large area by a facile one-step process. First, rough and random ZnO nanocrystals (NC), were produced by free-stabilizing aqueous synthesis. Therefore, a post thermal treatment at various temperatures ranging from 80 to 800 °C was necessary to obtain size-tunable and photoluminescent crystalline NP. The fabricated NP had both efficient UV photoluminescence and photocatalytic activity by photo-degradation of Methylene Blue (MB) dye. The annealed NP showed an absorption blue shift in the UV region with decreasing size. This shift was attributed to high quantum confinement effect since ZnO NP diameter reached values lower than the Bohr radius of ZnO (~2.7 nm). The photocatalytic activity displayed dependency on the particle’s size, number, and crystallinity. Subsequently, the NP were self-assembled inside poly(methyl methacrylate) (PMMA) nanoholes. Subsequently, large area substrate of homogenous properties ZnO NP was obtained. Moreover, the synthesis facility, photoemission and photocatalytic properties of ZnO NP could be a new insight into the realization of high performance and low cost UV laser devices.

Highlights

In recent years, the fabrication of highly luminescent semiconductor nanostructures with an efficient photocatalytic activity has emerged at the level of science and technology
ZnO photoluminescence is marked by two regions, the first is a confined peak corresponding to the near band edge (NBE) emission in the ultraviolet region of the emission corresponding to the near band edge (NBE) emission in the ultraviolet region of the emission spectrum, spectrum, which characterizes the exciton radiative recombination of the electrons and holes, and the which characterizes the exciton radiative recombination of the electrons and holes, and the second is second is a large intense defect level (DL) band in the visible zone [51,52,53]
A large intense defect level (DL) band in the visible zone [51,52,53]. This photoemission study aimed to examine the effects of the time and temperature of the. This photoemission study aimed to examine the effects of the time and temperature of the reaction reaction on the structural and optical properties of ZnO nanostructures

Summary

Introduction

The fabrication of highly luminescent semiconductor nanostructures with an efficient photocatalytic activity has emerged at the level of science and technology. ZnO nanostructures have a direct and wide band gap (~3.37 eV) besides their high exciton binding energy (60 meV) and rich defect chemistry structures [10]. They possess a strong oxidizing power and superior UV emission characteristics, in addition to high stability and room temperature luminescence [11,12]. These features, allowed by the large quantum confinement, make them greatly promising and attractive materials for various

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Conclusion