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Anchored atomic tungsten on a B<sub>40</sub> cage: a highly active and selective single-atom catalyst for nitrogen reduction

Wenying Li, Yibing Sun, Mengyang Li, Xiaoyu Zhang, Xiang Zhao, Jingshuang Dang

2020Physical Chemistry Chemical Physics13 citationsDOI

Abstract

In comparison with the prevalent 2D material-supported single atom catalysts (SACs), the design and fabrication of SACs with single molecule substrates are still challenging. Here we introduce a new type of SAC in which a recently identified all-boron fullerene B40 is employed as the support and its catalytic performance toward the nitrogen reduction reaction (NRR) process is explored in theory. Taking advantage of the novel heptagonal ring substructure on the sphere and the electron-deficient nature of boron, the atomic metals are facile to reside on B40 to form atomically dispersed η7-B40M exohedral complexes. Among a series of candidates, originating from the proper metal-adsorbate interactions, the atomic tungsten-decorated B40W is screened out as the most feasible catalyst for the NRR with a low over-potential and high selectivity to passivate the competitive hydrogen evolution process.

Topics & Concepts

TungstenCageCatalysisSelectivityNitrogenAtom (system on chip)Nitrogen atomChemistryHydrogenPassivationInorganic chemistryMaterials scienceNanotechnologyGroup (periodic table)Organic chemistryCombinatoricsLayer (electronics)Computer scienceMathematicsEmbedded systemAmmonia Synthesis and Nitrogen ReductionAdvanced Photocatalysis TechniquesElectrocatalysts for Energy Conversion
Anchored atomic tungsten on a B<sub>40</sub> cage: a highly active and selective single-atom catalyst for nitrogen reduction | Litcius