Regulating Au coverage for the direct oxidation of methane to methanol.
Yueshan XuDao-Xiong WuQinghua ZhangPeng RaoPeilin DengMangen TangJing LiYingjie HuaChongtai WangShengkui ZhongChunman JiaZhongxin LiuYijun ShenLin GuXin Long TianQuanbing LiuPublished in: Nature communications (2024)
The direct oxidation of methane to methanol under mild conditions is challenging owing to its inadequate activity and low selectivity. A key objective is improving the selective oxidation of the first carbon-hydrogen bond of methane, while inhibiting the oxidation of the remaining carbon-hydrogen bonds to ensure high yield and selectivity of methanol. Here we design ultrathin Pd x Au y nanosheets and revealed a volcano-type relationship between the binding strength of hydroxyl radical on the catalyst surface and catalytic performance using experimental and density functional theory results. Our investigations indicate a trade-off relationship between the reaction-triggering and reaction-conversion steps in the reaction process. The optimized Pd 3 Au 1 nanosheets exhibits a methanol production rate of 147.8 millimoles per gram of Pd per hour, with a selectivity of 98% at 70 °C, representing one of the most efficient catalysts for the direct oxidation of methane to methanol.
Keyphrases
- visible light
- carbon dioxide
- electron transfer
- reduced graphene oxide
- density functional theory
- hydrogen peroxide
- anaerobic digestion
- metal organic framework
- sensitive detection
- molecular dynamics
- blood pressure
- transition metal
- quantum dots
- healthcare
- signaling pathway
- gold nanoparticles
- nitric oxide
- gram negative
- room temperature