Low-Temperature Methane Oxidation Triggered by Peroxide Radicals over Noble-Metal-Free MgO Catalyst.
Ying-Juan HaoLi-Gang TianErhong DuanJixing LiuTian-Yuan QiWei-Qi KongXue-Han QiXinying LiuYing LiuJun ZhaoFa-Tang LiPublished in: ACS applied materials & interfaces (2020)
Methane is a greenhouse gas that contributes to global warming. Hence, effectively removing the low concentration (<1000 ppm) of methane in the environment is an issue that deserves research in the field of catalysis. In this study, oxygen-magnesium bivacancies are simultaneously imbedded into MgO by designing an in situ reduction combustion atmosphere for oxygen release and substituting magnesium with carbon to induce the formation of magnesium vacancies. The DFT calculations reveal that the surface electron density of MgO is improved by the oxygen vacancy structure and the substitution of Mg by C in bulk; this accelerates migration of the charge from the material surface to the adsorbed oxygen species, which leads to abundant surface peroxide species that enable activation and oxidation of methane at a low temperature (below 200 °C). This work could provide a concept for developing non-noble or transition metal oxides for low-temperature activation and conversion of alkanes in the thermocatalytic field through reactive oxygen species.
Keyphrases
- anaerobic digestion
- carbon dioxide
- reactive oxygen species
- transition metal
- density functional theory
- hydrogen peroxide
- visible light
- sewage sludge
- particulate matter
- municipal solid waste
- molecular docking
- ionic liquid
- single cell
- gene expression
- risk assessment
- room temperature
- solar cells
- air pollution
- highly efficient