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Pd nanocatalysts engineering for direct oxidation methane-to-methanol with 99.7% selectivity

Peilin Deng, Yueshan Xu, Daoxiong Wu, Ying Liang, Xue Zhang, Zhitong Wang, Liqiang Jing, Xinlong Tian

2025Nature Communications13 citationsDOIOpen Access PDF

Abstract

Pd catalysts demonstrate remarkable activity and selectivity for the direct oxidation methane-to-methanol (DOMM) under mild conditions. However, understanding the structure–performance relationship is challenging because Pd catalysts used in existing studies have complex polycrystalline structures. In this work, well-defined Pd nanocrystals with controlled morphologies are synthesized and used as model systems to investigate the origins of the observed structure-activity differences. Our findings indicate that DOMM activity is primarily governed by crystal facet type rather than nanocrystal size. The lower d-band center of the Pd {111} facet weakens the adsorption strength of critical intermediates, including *O2 and *OH species, promoting H2O2 generation and CH3OH formation, respectively. Consequently, {111}-dominated octahedral Pd nanocrystals achieve an exceptional CH3OH yield of 201.8 mmol·gPd−1·h−1, three times higher than that of their {100}-dominated hexahedral counterparts. These results provide key insights into the structure-dependent behavior of Pd catalysts and pave the way for designing high-performance catalysts for DOMM. Pd catalysts are promising for methane-to-methanol conversion, but structure–performance links remain unclear. This study uses facet-controlled Pd nanocrystals, revealing {111}-facets enhance methanol yield via optimal intermediate adsorption.

Topics & Concepts

Nanomaterial-based catalystSelectivityMethaneMethanolAnaerobic oxidation of methaneChemistryChemical engineeringCatalysisOrganic chemistryEngineeringCatalytic Processes in Materials ScienceCatalysis and Oxidation ReactionsElectrocatalysts for Energy Conversion