A series of supported WO3/TiO2 catalysts was prepared by a new synthesis procedure involving co-precipitation of an aqueous TiO(OH)2 and (NH4)10W12O41*5H2O slurry under controlled pH conditions. The morphological properties, surface WOx molecular structures, surface acidity and surface chemistry of the co-precipitated WO3/TiO2 catalysts were determined with BET, in situ Raman, in situ IR, steady-state NO/NH3/O2 SCR and NO/NH3-temperature-programmed surface reaction (TPSR) spectroscopy, respectively. Time-resolved isotopic 18O–16O exchange with IR spectroscopy demonstrated that tungsten oxide was present as surface WOx sites on the TiO2 support with mono-oxo O = WO4 coordination. In contrast to previous studies employing impregnation synthesis that found only surface one mono-oxo O = WO4 site (1010–1016 cm−1) on TiO2, the co-precipitation procedure resulted in the formation of two distinct surface WOx sites: mono-oxo O = WO4 (∼1012–1014 cm−1) and a second mono-oxo O = WO4 (∼983–985 cm−1). The new surface mono-oxo O = WO4 (∼983–985 cm−1) site is thought to be associated with surface defects on the co-precipitated titania support. The co-precipitated catalysts exhibited slightly enhanced SCR reactivity that is thought to be related to the presence of the new surface O = WO4 sites. Additional factors, however, may also be contributing. This is the first study that attempts to relate the molecular level structural properties of co-precipitated WO3-TiO2 catalysts with their surface reactivity for SCR.

Nanoparticles (NPs) with reactive oxygen species (ROS)-regulating ability have recently attracted great attention as promising agents for nanomedicine. In the present study, we have analyzed the effects of TiO2 defect structure related to the presence of stoichiometric (Ti4+) and non-stoichiometric (Ti3+ and Ti2+) titanium ions in the crystal lattice and TiO2 NPs aggregation ability on H2O2- and tBOOH-induced ROS production in L929 cells. Synthesized TiO2-A, TiO2-B, and TiO2-C NPs with varying Ti3+(Ti2+) content were characterized by XRD, TEM, SAXS, XPS, and optical spectroscopy methods. Given the role of ROS-mediated toxicity for metal oxide NPs, L929 cell viability and changes in the intracellular ROS levels in H2O2- and tBOOH-treated L929 cells incubated with TiO2 NPs have been evaluated. Our research shows that both the amount of non-stoichiometric Ti3+ and Ti2+ ions in the crystal lattice of TiO2 NPs and NPs aggregative behavior affect their catalytic activity, in particular, H2O2 decomposition and, consequently, the efficiency of aggravating H2O2- and tBOOH-induced oxidative damage to L929 cells. TiO2-A NPs reveal the strongest H2O2 decomposition activity aligning with their less pronounced additional effects on H2O2-treated L929 cells due to the highest amount of Ti3+(Ti2+) ions. TiO2-C NPs with smaller amounts of Ti3+ ions and a tendency to aggregate in water solutions show lower antioxidant activity and, consequently, some elevation of the level of ROS in H2O2/tBOOH-treated L929 cells. Our findings suggest that synthesized TiO2 NPs capable of enhancing ROS generation at concentrations non-toxic for normal cells, which should be further investigated to assess their possible application in nanomedicine as ROS-regulating pharmaceutical agents.