Low-temperature Thermocatalytic Removal of Formaldehyde in Air Using Copper Manganite Spinels.

The removal of formaldehyde (FA) is vital for indoor air quality management in light of its carcinogenic propensity and adverse environmental impact. A series of copper manganite spinel structures (e.g., CuMn 2 O 4 ) are prepared using the sol -gel combustion method and treated with reduction or oxidation pretreatment at 300 degrees C condition. Accordingly, CuMn 2 O 4 - O ( " O " suffix for oxidation pre-treatment in air) is identified as the best performer to achieve 100% conversion (X FA ) of FA (50 ppm) at 90 degrees C; its performance, if assessed in terms of reaction kinetic rate (r) at X FA = 10%, is 5.02E-03 mmol g -1 h -1 . The FA removal performance increases systematically with decreases in flow rate, FA concentration, and relative humidity (RH) or with increases in bed mass. The reaction pathways and intermediates of FA catalytic oxidation on CuMn 2 O 4 -A are studied with density functional theory simulations, temperature-programmed characterization experiments, and in -situ diffuse reflectance infrared Fourier transform spectroscopy. The synergistic combination of large quantities of adsorbed oxygen (O A ) species and oxidized metal species (e.g., Cu 2+ ) contribute to the enhanced catalytic performance of CuMn 2 O 4 - O to oxidize FA into CO 2 with the reaction intermediates of H 2 CO 2 (DOM), HCOO - , and CO. The present study is expected to provide valuable insights into the thermocatalytic oxidation of FA over spinel CuMn 2 O 4 materials and their catalytic performances in relation to the key process variables.