Degradation of pharmaceutical drug paracetamol via UV irradiation using Fe-TiO2 composite photocatalyst: statistical analysis and parametric optimization

In the present investigation, a novel Fe-TiO2 composite was fabricated by mixing fly ash (FA), foundry sand (FS), and bentonite clay for the degradation of paracetamol (PCM). This composite acts as a surface for immobilizing the TiO2 catalyst (using the dip-coating method) besides facilitating the leaching of iron (FA and FS) in acidic conditions. Leached iron (in the form of Fe(II), Fe(III), and total iron) promotes the photo-Fenton (with the addition of H2O2 in the system) while the surface-active TiO2 layer leads to photocatalysis, thus leading to in situ dual process combining photocatalysis and photo-Fenton in one system. This dual process led to a synergy of 75% in comparison to the photocatalysis and photo-Fenton process owing to the large production of center dot OH. Various parameters such as H2O2 dose (525 mg l(-1)), number of beads (80), degradation time (215 min), and volume (200 ml) were optimized, and 96.6% of reduction in PCM was observed. Durability study of catalyst showed a minor reduction in the activity of the catalyst after 30 cycles. The TiO2 catalyst was still intact as a film, and iron leaching was also occurring from the beads even after recycling, thus confirming their long-term durability in terms of dual effect. The stability and durability of the composite were confirmed by characteristic analysis such as SEM/EDS. Mineralization of PCM was concluded through the estimation of degradation by-products using GC-MS analysis followed by estimation of nitrate and nitrite ions.

Automated summary

In this study, a novel Fe-TiO2 composite was successfully used for the degradation of paracetamol, combining photocatalysis and photo-Fenton in situ. After optimizing various parameters, a reduction of 96.6% in PCM was observed.