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Formaldehyde Decomposition from −20 °C to Room Temperature on a Mn–Mullite YMn<sub>2</sub>O<sub>5</sub> Catalyst

Fangxie Shen, Xiang Wan, Lijing Wang, Chunning Zhao, Shen Zhang, Anqi Dong, Kai Shi, Haijun Zhang, Xiaomeng Zhou, Kunpeng He, Yinchang Feng, Weichao Wang

2022Environmental Science & Technology27 citationsDOI

Abstract

Large ambient temperature changes (−20–>25 °C) bring great challenges to the purification of the indoor pollutant formaldehyde. Within such a large ambient temperature range, we herein report a manganese-based strategy, that is, a mullite catalyst (YMn2O5) + ozone, to efficiently remove the formaldehyde pollution. At −20 °C, the formaldehyde removal efficiency reaches 62% under the condition of 60,000 mL gcat–1 h–1. As the reaction temperature is increased to −5 °C, formaldehyde and ozone are completely converted into CO2, H2O, and O2, respectively. Such a remarkable performance was ascribed to the highly reactive oxygen species generated by ozone on the YMn2O5 surface based on the low temperature-programed desorption measurements. The in situ infrared spectra showed the intermediate product carboxyl group (−COOH) to be the key species. Based on the superior performance, we built a consumable-free air purifier equipped with mullite-coated ceramics. In the simulated indoor condition (25 °C and 30% relative humidity), the equipment can effectively decompose formaldehyde (150 m3 h–1) without producing secondary pollutants, rivaling a commercial removal efficiency. This work provides an air purification route based on the mullite catalyst + ozone to remove formaldehyde in an ambient temperature range (−20–>25 °C).

Topics & Concepts

MulliteDecompositionFormaldehydeCatalysisMaterials scienceMineralogyChemistryMetallurgyOrganic chemistryCeramicCatalysis and Oxidation ReactionsCatalytic Processes in Materials SciencePigment Synthesis and Properties
Formaldehyde Decomposition from −20 °C to Room Temperature on a Mn–Mullite YMn<sub>2</sub>O<sub>5</sub> Catalyst | Litcius