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Article Abstract
Controlling the chemical environments of the active metal atom including both coordination number (CN) and local composition (LC) is vital to achieve active and stable single-atom catalysts (SACs), but remains challenging. Here we synthesized a series of supported Pt SACs by depositing Pt atoms onto the pretuned anchoring sites on nitrogen-doped carbon using atomic layer deposition. In hydrogenation of -chloronitrobenzene, the Pt SAC with a higher CN about four but less pyridinic nitrogen (N) content exhibits a remarkably high activity along with superior recyclability compared to those with lower CNs and more N. Theoretical calculations reveal that the four-coordinated Pt atoms with about 1 eV lower formation energy are more resistant to agglomerations than the three-coordinated ones. Composition-wise decrease of the Pt-N bond upshifts gradually the Pt-5 center, and minimal one Pt-N bond features a high-lying Pt-5 state that largely facilitates H dissociation, boosting hydrogenation activity remarkably.
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