Abstract
Supported titanium dioxide catalysts were used in a photocatalytic flat cell reactor to remove organic micropollutants from real wastewater. Catalysts based on stainless steel mesh with a porous coating made of titanium dioxide nanoparticles with predominantly anatase modification were used. The influence of the retention time, and light output, and the effect of hydrogen peroxide on the degradation were examined. The kinetics of the degradation of the parent substances was determined by liquid chromatography-tandem mass spectrometry. As a result, first-order degradation kinetics could be confirmed for all substances. The irradiance had no linear influence on the degradation of the compounds. Hydrogen peroxides were added to the wastewater to be treated, as electron acceptors and boosters, and alone had no great oxidative effect on the parent substances. The combination of photocatalysis with the addition of hydrogen peroxide as an electron acceptor had great synergetic effects which can reduce the required energy of the process through a short retention time. The process is suitable for the removal of micropollutants from wastewater.
Highlights
Organic micropollutants, such as pharmaceutical residues, industrial chemicals, or pesticides, are only degraded partially and retained in conventional wastewater treatment plants (Abegglen & Siegrist )
A Dionex R3000 system with gradient pump and autosampler was used for high-performance liquid chromatography (HPLC)
This work aimed to demonstrate the effectiveness of a photocatalytic flat cell reactor as a further treatment stage in a real wastewater matrix
Summary
Organic micropollutants, such as pharmaceutical residues, industrial chemicals, or pesticides, are only degraded partially and retained in conventional wastewater treatment plants (Abegglen & Siegrist ). Treated wastewater from municipal wastewater treatment plants represents a major input path for organic micropollutants, especially pharmaceutical residues, into the environment (Bergmann et al ). For this reason, an additional (further) treatment. This is usually arranged following the biological treatment. Advanced oxidation processes (AOPs), which use hydroxyl radicals at ambient temperature as oxidants (Wang & Xu ), are not yet used in technical systems as a further treatment stage.
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