Transition Metal-Doped C 20 Fullerene-Based Single-Atom Catalysts with High Catalytic Activity for Hydrogen Dissociation Reaction.

Hydrogen dissociation is a key step in almost all hydrogenation reactions; therefore, an efficient and cost-effective catalyst with a favorable band structure for this step is highly desirable. In the current work, transition metal-based C ₂₀ (M@C ₂₀ ) complexes are designed and evaluated as single-atom catalysts (SACs) for hydrogen dissociation reaction (HDR). Interaction energy ( E _int ) analysis reveals that all the M@C ₂₀ complexes are thermodynamically stable, whereas the highest stability is observed for the Ni@C ₂₀ complex ( E _int = -6.14 eV). Moreover, the best catalytic performance for H ₂ dissociation reaction is computed for the Zn@C ₂₀ catalyst ( E _ads = 0.53 eV) followed by Ti@C ₂₀ ( E _ads = 0.65 eV) and Sc@C ₂₀ ( E _ads = 0.76 eV) among all considered catalysts. QTAIM analyses reveal covalent or shared shell interactions in H ₂ * + M@C ₂₀ systems, which promote the process of H ₂ dissociation over M@C ₂₀ complexes. NBO and EDD analyses declare that transfer of charge from the metal atom to the antibonding orbital of H ₂ causes dissociation of the H-H bond. Overall outcomes of this study reveal that the Zn@C ₂₀ catalyst can act as a highly efficient, low-cost, abundant, and precious metal-free SAC to effectively catalyze HDR.
Competing Interests: The authors declare no competing financial interest.
(© 2023 The Authors. Published by American Chemical Society.)