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Partial-coverage assembly of graphdiyne-derived fragment-protected Cu(I) clusters generates an ordered single-metal site catalyst

Shuai Chen, Xi Fan, Shuai Yan, Morgan McKee, Alexandre Terry, Chen Gao, Mahsa Abdolmaleki, Jost Heise, Minmin Chen, Yves Kayser, Serena DeBeer, Jian Zhang, Nikolay Kornienko

2025National Science Review5 citationsDOIOpen Access PDF

Abstract

ABSTRACT Isolated single-site catalysts (ISSCs) have emerged as promising materials for energy conversion and storage. However, current approaches for inorganic nanocatalysts are often ineffective in achieving precisely ordered periodic atomic arrangements of active sites, often leading to a random distribution of active-site motifs on an inorganic substrate. In this work, we introduce a novel partial-coverage-assembly strategy, leveraging graphdiyne-derived fragment ligands, to synthesize a unique Cu nanocluster catalyst with an ordered periodic arrangement of isolated single-metal Cu sites [Cu4(TFA)4(DPBD)2, Cu-SMS], while maintaining identical atomicity and a homogeneous coordination microenvironment. This strategic approach significantly enhances the electron transport capability by incorporating graphdiyne-inspired bridging ligands as compared to non-coverage-assembled Cu-MMS (MMS: multiple-metal site). As a result, the Cu-SMS nanocluster catalyst exhibited superior performance in electrocatalytic nitrate reduction to ammonia, achieving a Faradaic efficiency exceeding 99%, surpassing all previously reported atomic precise metal nanocluster catalysts. Through a combination of in situ attenuated total reflection surface-enhanced infrared absorption spectroscopy, electrochemical mass spectrometry and density functional theory calculations, we unraveled a detailed mechanistic pathway of nitrate reduction on Cu-SMS, highlighting the role of key intermediates (*NO2, *NO, *NHO, *NHOH, *NH2OH, *NH2) and identifying the rate-determining step. In all, these findings present a novel methodology for synthesizing periodic SMS catalysts, emphasizing the emergent catalytic behaviors of precisely ordered metal clusters in heterogeneous catalysis.

Topics & Concepts

CatalysisNanomaterial-based catalystMaterials scienceHomogeneousDensity functional theoryNanotechnologyElectrochemistryMetalFaraday efficiencyChemical physicsHeterogeneous catalysisCombinatorial chemistryChemistryReduction (mathematics)Active siteReflection (computer programming)Chemical engineeringAtomicityDispersion (optics)Absorption spectroscopyAbsorption (acoustics)Ammonia Synthesis and Nitrogen ReductionCO2 Reduction Techniques and CatalystsElectrocatalysts for Energy Conversion
Partial-coverage assembly of graphdiyne-derived fragment-protected Cu(I) clusters generates an ordered single-metal site catalyst | Litcius