Optimization of flocculation conditions for the separation of TiO2 particles in coagulation-photocatalysis hybrid water treatment

• Optimal flocculation conditions for the separation of TiO2 photocatalysts are investigated.
• The TiO2 separation efficiency is highly sensitive to coagulant dosages and G values.
• Mild flocculation at a low G value is more effective than tapered flocculation.
• Sand filtration after flocculation reduces water turbidity comparable to microfiltration.

TiO2 mediated photocatalysis can decompose organic micropollutants (e.g., 1,4-dioxane) in water, but the removal of used TiO2 particles is challenging. Although retrofitting enhances the particle separation efficiency, optimizing a coagulation/flocculation process should be most suitable for existing treatment plants. Therefore, the present study investigated the separation characteristics of TiO2 particles added to drinking water treatment processes along with a polyaluminum coagulant. TiO2 photocatalysts were able to achieve significant degradation of 1,4-dioxane (∼100% within 50 min) as well as dissolved organic matter (∼75% within 150 min) at a TiO2 dose of 1.0 g/L under UV irradiation. Although the TiO2 particle separation efficiency was sensitive to G values, maximal removal occurred at a G value of <34 s−1 with a coagulant concentration of >8 mg/L as Al2O3. Sand filters had the capability to remove residual turbid materials and thus, the turbidity of the final product water dropped to as low as 0.1 NTU when the coagulation/flocculation process was preceded. The final effluent quality was comparable to that of a 0.45-μm membrane filter. The post separation of the TiO2 photocatalysts dispersed for emergency water treatment to degrade 1,4-dixoane was successfully achieved with an optimal coagulant dose, proper flocculation, and sand filtration.

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