Journal
APPLIED CATALYSIS B-ENVIRONMENTAL
Volume 320, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.apcatb.2022.121994
Keywords
Formaldehyde; CO2-storage material; ?-MnO2; Catalytic oxidation; Oxygen vacancies
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Formaldehyde removal is crucial for health, but developing high-performance non-precious metal catalysts remains challenging. This study synthesized a novel composite catalyst through dopant modification, which showed enhanced catalytic activity and revealed a synergistic catalytic mechanism.
Formaldehyde removal is vital to health, but the construction of high-performance non-precious metal catalysts still faces great challenges, in which increasing oxygen vacancies by dopant modification is an advanced strategy to enhance catalytic activity. In this work, a novel epsilon-MnO2/Mn2V2O7 composite catalyst with a synergistic effect was synthesized on the basis of a thermal decomposition strategy. Meanwhile, the precursor for the catalyst was synthesized from the reaction among CO2-storage material, Mn2+, and vanadate without additional template agents and surfactants. Aided by the catalyst, the degradation rate of a 20 mg/L 10 mL formaldehyde (HCHO) solution can reach 72.0% and maintain above 67% after 5 cycles at 30 degrees C for 1 h. Subsequently, the as-obtained synergistic catalytic mechanism showed that the high-valent V5+ may partially replace Mn4+ in the MnO2 framework, promoting the formation of enriched oxygen vacancies (V4+--Mn3+) on the surface of the composite catalyst via the redox coupling of Mn4+/Mn3+ and V5+/V4+. This leads to an increase in adsorbed oxygen, significantly improving the degradation performance of HCHO. This work provides a novel and advanced strategy for dopant modification to develop superior non-precious metal catalysts.
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