Na-Au界面工学によりメタン酸化の高選択性を実現 （Scientists Achieve Near-Quantitative Selectivity for Methane Oxidation via Na-Auδ?? Interfacial Engineering）

2026-05-27 中国科学院（CAS）

Selective methane conversion to methanol and acetic acid via ·OH/CH₃ radical coupling enabled by Na–Au^δ⁻ interfacial sites that generate H₂O₂ and ·OH (Image by LI Xianquan)

＜関連情報＞

• https://english.cas.cn/newsroom/research-news/202605/t20260528_1160005.shtml
• https://onlinelibrary.wiley.com/doi/10.1002/anie.202525250

制御されたその場でのH₂O₂生成によるO₂を用いた選択的メタン水酸化を促進するためのNa–Au δ−界面の設計 Engineering Na–Auδ− Interfaces for Enhancing Selective Methane Hydroxylation With O2 via Controlled In Situ H2O2 Generation

Xianquan Li, Weibin Xu, Jian Zhao, Yi Ji, Aijing Hao, Yujia Zhao, Haohan Li, Lin Li, Pan Gao, Xiaodong Wang, Guangjin Hou
Angewandte Chemie International Edition  Published: 05 May 2026
DOI:https://doi.org/10.1002/anie.202525250

ABSTRACT

The selective oxidation of methane (CH₄) to value-added oxygenates (e.g., methanol, acetic acid) under mild conditions remains a pivotal yet formidable challenge in catalysis. Herein, we design Na-decorated Au nanoparticles supported on mordenite (MOR) nanosheets, which leverage electronic metal-support interactions to dynamically tune the electronic state and local microenvironment of the active sites for directional C─H activation under CH₄/CO/O₂/H₂O at 150° C. This catalyst affords near-100% selectivity toward hydroxylated oxygenates derived from CH₄ with a remarkable productivity of 2.02 mmol·g_cat⁻¹·h⁻¹, outperforming most reported catalysts under comparable conditions. In situ spectroscopic studies and density functional theory (DFT) calculations reveal that Na-induced electronic modulation creates a unique Na-Au^δ− interfacial structure, driving the Au species into an electron-deficient state that boosts the oxygenate formation rate by more than an order of magnitude compared to the pristine Au^δ− sites. The Na-Au^δ− interface enhances catalysis by enabling accelerated in -situ H₂O₂ generation and concurrent C─H bond activation, while avoiding methanol overoxidation, thereby boosting overall catalytic performance. This work deciphers the dynamic role of in situ generated H₂O₂ in methane activation under mild conditions, and establishes electronic microenvironment engineering as a powerful strategy for the selective and controllable oxidation valorization of methane.