Selective Synergistic Catalytic Elimination of NO x and CH 3 SH via Engineering Deep Oxidation Sites against Toxic Byproducts Formation.

NO x and CH 3 SH as two typical air pollutants widely coexist in various energy and industrial processes; hence, it is urgent to develop highly efficient catalysts to synergistically eliminate NO x and CH 3 SH. However, the catalytic system for synergistically eliminating NO x and CH 3 SH is seldom investigated to date. Meanwhile, the deactivation effects of CH 3 SH on catalysts and the formation mechanism of toxic byproducts emitted from the synergistic catalytic elimination reaction are still vague. Herein, selective synergistic catalytic elimination (SSCE) of NO x and CH 3 SH via engineering deep oxidation sites over Cu-modified Nb-Fe composite oxides supported on TiO 2 catalyst against toxic CO and HCN byproducts formation has been originally demonstrated. Various spectroscopic and microscopic characterizations demonstrate that the sufficient chemisorbed oxygen species induced by the persistent electron transfer from Nb-Fe composite oxides to copper oxides can deeply oxidize HCOOH to CO 2 for avoiding highly toxic byproducts formation. This work is of significance in designing superior catalysts employed in more complex working conditions and sheds light on the progress in the SSCE of NO x and sulfur-containing volatile organic compounds.