Departament d'Enginyeria Química, Universitat de Barcelona, Martí i Franquès 1, 08028 Barcelona, Spain.
Plataforma Solar de Almería (CIEMAT), Carretera Senés, Km 4, 04200 Tabernas, Almería, Spain.
J Hazard Mater. 2014 Jan 30;265:177-84. doi: 10.1016/j.jhazmat.2013.11.064. Epub 2013 Dec 7.
Interferences from many sources can affect photo-Fenton reaction performance. Among them, catalyst inhibition can be caused by the complexation and/or precipitation of iron species by the organic matter and salts present in the reaction media. This is the case of the oxidation of effluents containing organophosphorous fosetyl-Al. The degradation of this fungicide generates phosphate anions that scavenge iron and hinder Fe(II) availability. Experimental design was applied to artificially enlighten photo-Fenton reaction, in order to evaluate fosetyl-Al degradation. The performed experiments suggested how iron inhibition takes place. The monitoring of photo-Fenton reaction over a mixture of fosetyl-Al with other two pesticides also showed the interferences caused by the presence of the fungicide on other species degradation. Solar empowered photo-Fenton was also essayed for comparison purposes. Artificial and solar light photo-Fenton reactions were revealed as effective treatments for the elimination of tested fungicide. However, the phosphate ions generated during fosetyl oxidation decreased iron availability, what hampered organic matter degradation.
多种来源的干扰会影响光芬顿反应性能。其中,反应介质中存在的有机物和盐会导致铁物种的络合和/或沉淀,从而抑制催化剂。这就是含有有机磷膦酰基 -Al 的废水的氧化情况。这种杀菌剂的降解会产生磷酸根阴离子,这些阴离子会捕获铁并阻碍 Fe(II)的可用性。实验设计被应用于人工阐明光芬顿反应,以评估膦酰基 -Al 的降解。进行的实验表明了铁抑制是如何发生的。在含有其他两种农药的膦酰基 -Al 混合物上进行的光芬顿反应监测也表明了杀菌剂的存在对其他物种降解的干扰。还为比较目的尝试了太阳能增强的光芬顿。人工和太阳能光芬顿反应被证明是消除测试杀菌剂的有效处理方法。然而,在膦酰基氧化过程中产生的磷酸根离子会降低铁的可用性,从而阻碍有机物的降解。