Currently, the development of TiO2-based semiconductors carry out drawback at photocatalytic commercial applications for photodegradation of pollutants gases. The photocatalytic limitations are i) inefficient absorption of visible light that inhibits the photogeneration of free electron and hole pairs, ii) small surface area and iii) high rate of electron to hole recombination. The aim of this study was the synthesis and characterization of a new visible light sensitive nanohybrids based on ferrititanate exfoliated nanosheets and a charge transfer complex (TiO2-ACAC) by controlling the [Ti] anatase/[Ti] ferrititanate molar ratio and applying two different synthesis route. Besides, it was studied the individual components. The nanohybrids were synthesized through physical mixture route and soft chemical route, named respectively as MF and HM-1. The molar ratios used in this work were 10, 5 and 2. All of the heterostructures presented high surface area (higher than 100m2/g) and partial restacking of lamellar structure. The nanohybrids with higher molar ratio and synthesized through physical mixture showed the greatest photocatalytic activity with more efficient photo-oxidation of gas NOx than the nanohybrids synthesized through soft chemical route. The nanohybrid with better performance, the MF with ratio 10, obtained a NO conversion of approximately 80 percent after 5min and gradual reduction of conversion to 25 percent after 2h. Nevertheless, the TiO2-ACAC nanoparticles component calcined at 300 C degrees presented total sensitivity at the range of visible light, surface area of 137m2/g and conversion higher than 95 percent with partial photocatalytic deactivation to 38.5 percent after 2h. The results of TiO2-ACAC system studied can be described due to its nanometric structure, high surface area and, mainly, for the presence of strongly interacting between acetylacetone with Ti ions from anatase surface, while maximized and stabilized the photogeneration of electron-hole pairs and reactive oxidizing species (ROS), .O2 -. However, the lower performance of the nanohybrids ascribed to the oxygen vacancies and Fe3+ ions that acting as electron trapping center reducing the formation of ROS.