Abstract
It is significant to render visible-light photocatalytic activity to undoped ZnO nanostructures via intrinsic defect engineering. In this work, undoped ZnO nanocrystals were derived via co-precipitation synthesis. The resulting ZnO nanocrystals were characterized by means of X-ray diffraction, scanning electron microscopy, photoluminescence spectroscopy, and ultraviolet-visible absorption spectroscopy, respectively. The visible-light photocatalytic activity of the products were characterized by monitoring the decomposition of methyl orange in water under visible-light illumination of a 300 W halogen lamp. It is found that undoped ZnO nanocrystals exhibit visible-light photocatalytic activity with their first-order rate constant up to 4.6 × 10−3 min−1. Density functional calculations show that oxygen vacancies create deep energy levels at EV + 0.76 eV in the bandgap of ZnO. In conjunction with the density functional calculations, the photocatalytic degradation of methyl orange under visible-light irradiation provides direct evidence that oxygen vacancies in ZnO nanocrystals yield the visible-light photocatalytic activity. Our results demonstrate that visible-light photocatalytic activity can be endowed to undoped ZnO nanocrystals by manipulating the intrinsic defects in ZnO. Intrinsic defect-modulated ZnO photocatalysts thus represent a powerful configuration for further development toward visible-light responsive photocatalysis.
Highlights
The increase in hazardous organic pollution generates high demand for ecologically clean solutions
In conjunction with the electronic structures derived via density functional calculations, our results indicate that intrinsic defect engineering seems to be effective in rendering the visible-light absorption to undoped ZnO
Visible-light responsive photocatalytic activity of undoped ZnO nanocrystals has been evaluated under the visible-light illumination of a 300 W halogen lamp
Summary
The increase in hazardous organic pollution generates high demand for ecologically clean solutions. Being able to use the abundant solar light, semiconductor photocatalysis is one of the most promising solutions to decomposing numerous organic pollutants in water [1,2]. ZnO nanocrystals have attracted a lot of attention because of their advantages of suitable energy band positions, low toxicity, and high chemical stability [3,4,5,6]. It is a general belief that perfect ZnO cannot exhibit visible-light photocatalytic activity since the bandgap of perfect ZnO is too large (3.37 eV). Doping ZnO with transitional elements can create midgap states in the bandgap of ZnO, thereby rendering ZnO with visible-light photocatalytic activity by shifting its optical absorption to the visible spectral regime [7,8,9,10,11,12,13,14,15]
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