Methyl Orange Photo-Degradation by TiO2 in a Pilot Unit under Different Chemical, Physical, and Hydraulic Conditions

The photo-catalytic degradation of a textile azo-dye as Methyl Orange was studied in an innovative unit constituted by a channel over which a layer of titanium dioxide (TiO2) catalyst in anatase form was deposited and activated by UVB irradiation. The degradation kinetics were followed after variation of the chemical, physical, and hydraulic/hydrodynamic parameters of the system. For this purpose, the influence of the TiO2 dosage (g/cm(3)), dye concentration (mg/L), pH of the solution, flow-rate (L/s), hydraulic load (cm), and irradiation power (W) were evaluated on the degradation rates. It was observed that the maximum dosage of TiO2 was 0.79 g/cm(3) while for higher dosage a reduction of homogeneity of the cement conglomerate occurred. The Langmuir-Hinshelwood (LH) kinetic model was followed up to a dye concentration around 1 mg/L. It was observed that with the increase of the flow rate, an increase of the degradation kinetics was obtained, while the further increase of the flow-rate associated with the modification of the hydraulic load determined a decrease of the kinetic rates. The results also evidenced an increase of the kinetic rates with the increase of the UVB intensity. A final comparison with other dyes such as Methyl Red and Methylene Blue was carried out in consideration of the pH of the solution, which sensibly affected the removal efficiencies.

Automated summary

The photo-catalytic degradation of a textile azo-dye Methyl Orange was studied in an innovative unit with a titanium dioxide catalyst layer, activated by UVB irradiation. Various parameters such as TiO2 dosage, dye concentration, pH, flow-rate, hydraulic load, and irradiation power were found to influence degradation rates. An increase in flow rate led to higher degradation kinetics, while further increase associated with modification of hydraulic load resulted in lower rates. Additionally, the kinetic rates increased with higher UVB intensity.