Low cost UVA-LED as a radiation source for the photo-Fenton process: a new approach for micropollutant removal from urban wastewater

Light Emitting Diode (LED) technology has matured sufficiently to be considered as an alternative UVA radiation source in photoreactors. Currently, low energy consuming LEDs with a wide range of wavelengths and radiant flux are readily available. In this study, UVA-LEDs were used as a radiation sour...

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Published in:Photochemical & photobiological sciences 2017-01, Vol.16 (1), p.72-78
Main Authors: de la Obra, I, Esteban García, B, García Sánchez, J. L, Casas López, J. L, Sánchez Pérez, J. A
Format: Article
Language:English
Subjects:
Biochemistry
Biomaterials
Chemistry
Colorimetry
Hydrogen Peroxide - analysis
Hydrogen Peroxide - chemistry
Iron - analysis
Iron - chemistry
Light
Photolysis - radiation effects
Physical Chemistry
Plant Sciences
Ultraviolet Rays
Waste Water - analysis
Water Pollutants, Chemical - chemistry
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Summary:Light Emitting Diode (LED) technology has matured sufficiently to be considered as an alternative UVA radiation source in photoreactors. Currently, low energy consuming LEDs with a wide range of wavelengths and radiant flux are readily available. In this study, UVA-LEDs were used as a radiation source for the photo-Fenton process as tertiary treatment. The water matrix used was a simulated secondary effluent doped with 200 μg L −1 of the pesticide acetamiprid (ACTM) due to its recalcitrant nature. All experiments were carried out in a LED-box reactor at pH 2.8. The main purpose of this research was to gain some insight into the relationships among energy supply, LED consumption, UVA irradiance and reaction rate. The effect of LED wavelength on energy efficiency for ACTM degradation was studied by varying the iron concentration and liquid depth. Three wavelengths (365, 385 and 400 nm) and two iron concentrations (5 and 11 mg L −1 ) for two different liquid depths (5 and 15 cm) were evaluated in order to obtain more energy efficient conditions. The results suggest that while the wavelength of 365 nm with 11 mg Fe 2+ L −1 was the best condition for ACTM degradation, the wavelength of 385 nm had slower kinetics, but higher energy efficiency. A UVA-LED driven photo-Fenton process is shown as a feasible technology for micropollutant removal. The photoreactor design, which strongly depends on the energy efficiency and LED wavelength, needs to be carried out using parameters such as Electrical-Energy-per-Order ( E EO ).
ISSN:1474-905X
1474-9092
DOI:10.1039/c6pp00245e