%0 Journal Article %1 rott2017removal %A Rott, Eduard %A Minke, Ralf %A Bali, Ulusoy %A Steinmetz, Heidrun %D 2017 %I Elsevier %J Water research %K %P 345-354 %R 10.1016/j.watres.2017.06.009 %T Removal of phosphonates from industrial wastewater with UV/feII, fenton and UV/fenton treatment %V 122 %X Phosphonates are an important group of phosphorus-containing compounds due to their increasing industrial use and possible eutrophication potential. This study involves investigations into the methods UV/FeII, Fenton and UV/Fenton for their removal from a pure water matrix and industrial wastewaters. It could be shown that the degradability of phosphonates by UV/FeII (6 kWh/m3) in pure water crucially depended on the pH and was higher the less phosphonate groups a phosphonate contains. The UV/FeII method is recommended in particular for the treatment of concentrates with nitrogen-free phosphonates, only little turbidity and a low content of organic compounds. Using Fenton reagent, the degradation of polyphosphonates was relatively weak in a pure water matrix (<20% transformation to o-PO43-). By means of the Photo-Fenton method (6 kWh/m3), those phosphonates with the smallest numbers of phosphonate groups were easier degraded as well at pH 3.5 in a pure water matrix (o-PO43- formation rates of up to 80%). Despite an incomplete transformation of organically bound phosphorus to o-PO43- with Fenton reagent in an organically highly polluted wastewater (max. 15%), an almost total removal of the total P occurred. The most efficient total P elimination rates were achieved in accordance with the following Fenton implementation: reaction → sludge separation (acidic) → neutralization of the supernatant → sludge separation (neutral). Accordingly, a neutralization directly after the reaction phase led to a lower total P removal extent.

@article{rott2017removal, abstract = {Phosphonates are an important group of phosphorus-containing compounds due to their increasing industrial use and possible eutrophication potential. This study involves investigations into the methods UV/FeII, Fenton and UV/Fenton for their removal from a pure water matrix and industrial wastewaters. It could be shown that the degradability of phosphonates by UV/FeII (6 kWh/m3) in pure water crucially depended on the pH and was higher the less phosphonate groups a phosphonate contains. The UV/FeII method is recommended in particular for the treatment of concentrates with nitrogen-free phosphonates, only little turbidity and a low content of organic compounds. Using Fenton reagent, the degradation of polyphosphonates was relatively weak in a pure water matrix (<20% transformation to o-PO43-). By means of the Photo-Fenton method (6 kWh/m3), those phosphonates with the smallest numbers of phosphonate groups were easier degraded as well at pH 3.5 in a pure water matrix (o-PO43- formation rates of up to 80%). Despite an incomplete transformation of organically bound phosphorus to o-PO43- with Fenton reagent in an organically highly polluted wastewater (max. 15%), an almost total removal of the total P occurred. The most efficient total P elimination rates were achieved in accordance with the following Fenton implementation: reaction → sludge separation (acidic) → neutralization of the supernatant → sludge separation (neutral). Accordingly, a neutralization directly after the reaction phase led to a lower total P removal extent.}, added-at = {2023-08-31T15:02:40.000+0200}, author = {Rott, Eduard and Minke, Ralf and Bali, Ulusoy and Steinmetz, Heidrun}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2da9925808b291586031c50ebaa63a413/puma-wartung}, doi = {10.1016/j.watres.2017.06.009}, interhash = {183d8322f81979dcd8ba404348905174}, intrahash = {da9925808b291586031c50ebaa63a413}, issn = {{0043-1354} and {1879-2448}}, journal = {Water research}, keywords = {}, language = {eng}, pages = {345-354}, publisher = {Elsevier}, timestamp = {2023-08-31T13:02:40.000+0200}, title = {Removal of phosphonates from industrial wastewater with UV/feII, fenton and UV/fenton treatment}, volume = 122, year = 2017 }