Porous TiO2 thin film-based photocatalytic windows for an enhanced operation of optofluidic microreactors in CO2 conversion

Using a photocatalytic window can simplify the design of an optofluidic micro-reactor, providing also a more straightforward operation. Therefore, the development of TiO2 coatings on glass substrates seems appealing, although a priori they would imply a reduced accessible area compared with supported nanoparticle systems. Considering this potential drawback, we have developed an endurable photocatalytic window consisting on an inner protective SiO2 layer and an outermesoporous anatase layerwith enhanced surface area and nanoscopic crystallite size (9-16 nm) supported on a glass substrate. The designed photocatalytic windows are active in the CO2-to-methanol photocatalytic transformation, with maximum methanol yield (0.52 mu mol.h(-1).cm(-2)) for greatest porosity values and minimum crystallite size. Compared with benchmark supported nanoparticle systems, the nanoscopic thickness of the coatings allowed to save photoactive material using only 11- 22 mu g.cm(-2), while its robustness prevented the leaching of active material, thus avoiding the decay of performance at long working periods.

Automated summary

By developing a durable photocatalytic window with an inner SiO2 layer and an outer mesoporous anatase layer on a glass substrate, it can act in the photocatalytic transformation of CO2 to methanol. This design saves photoactive material while maintaining robustness to prevent performance decay during long working periods.