Abstract
Small volumes (100 mL) of acidic aqueous solutions with 30-200 mg L-1 TOC of the toxic azo dye Acid Red 1 (AR1) have been comparatively treated by various electrochemical advanced oxidation processes (EAOPs). The electrolytic system consisted of a BDD anode able to produce ·OH and an air-diffusion cathode that generated H2O2, which subsequently reacted with added Fe2+ to yield additional ·OH from Fenton’s reaction. Under optimized conditions (i.e., 1.0 mM Fe2+, 60 mA cm-2, pH 3.0, 35 ºC), the analysis of the initial rates for decolourization and AR1 decay assuming a pseudo-first-order kinetics revealed a much higher rate constant for photoelectro-Fenton (PEF, ~ 2.7x10-3 s-1) compared to electro-Fenton (EF, ~ 0.6x10-3 s-1). Mineralization after 180 min was also greater in the former treatment (90 % vs 63 %). The use of UV radiation in PEF contributed to Fe(III) photoreduction as well as to photodecarboxylation of refractory intermediates, yielding a mineralization current efficiency as high as 85% during the treatment of solutions of 200 mg L-1 TOC. Primary reaction intermediates included three aromatic derivatives with the initial naphthalenic structure and four molecules only featuring benzenic rings, which were totally mineralized in PEF.
Highlights
Great attention has been paid to the electrochemical advanced oxidation processes (EAOPs) based on Fenton’s reaction chemistry for water decontamination [1]
Under the present EO conditions, given the weak oxidation power of H2O2, the organic matter can be mainly degraded by boron-doped diamond (BDD)( OH) formed via reaction (5)
These trials aimed at exploring the possibility of enhancing the decolourization and mineralization kinetics, which is based on the fact that the applied current determines the yield of BDD( OH) formed via reaction (5) as well as that of OH via reaction (2) because it depends on the H2O2 formation rate and Fe2+
Summary
Great attention has been paid to the electrochemical advanced oxidation processes (EAOPs) based on Fenton’s reaction chemistry for water decontamination [1]. The use of UV radiation in PEF contributed to Fe(III) photoreduction as well as to photodecarboxylation of refractory intermediates, yielding a mineralization current efficiency as high as 85% during the treatment of solutions of 200 mg L-1 TOC.
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