Catalytic oxidation mechanism of NO to HNO3 on TiO2 (101) and (001) surfaces and the influence factors on NO removal: A DFT study

Theoretical study on the selective catalytic oxidation of NO to form HNO3 on the different TiO2 (001) and (101) surfaces was performed by DFT calculations. The addition of additional NO molecules to the oxidation process also is discussed. The result shows that HNO3 is more easy to generate on (001) than (101) surface. The adsorbed H atom on surface is beneficial for the transformation of O-2 to the superoxide radical (O-2(center dot-)) that has a favorable role for the oxidation of NO on surface. In addition, it is manifestly demonstrated that the participation of the additional NO in the reaction of NO and O-2 not only modifies the known NO oxidation pathway (NO -> NO2 -> HNO3), but also affects the existence of the product HNO3. The trans-ONONO2 can firstly be formed if the additional NO molecule involves in the oxidation reaction in the beginning. When the additional NO molecule encounter with the precursor (H center dot center dot center dot NO3) of oxidation product (HNO3), it can improve the formation of HONO not HNO3. This study gains more insight into the mechanism of NO oxidation and has a potential atmospheric importance.

Automated summary

Theoretical study on the selective catalytic oxidation of NO to form HNO3 on different TiO2 surfaces found that HNO3 is easier to generate on certain surfaces, with the addition of extra NO molecules affecting the reaction pathway and product formation. This research provides deeper insight into the mechanism of NO oxidation and its potential atmospheric significance.