AI Article Synopsis
- The study addresses the trade-off between activity and selectivity in acetylene semi-hydrogenation by developing a new Au@PdCu core-shell nanocatalyst that enhances both properties.
- The nanocatalyst achieved 100% acetylene conversion and 92.4% ethylene selectivity at 122 °C, with performance 3.3 times better than a traditional PdCu alloy.
- Advanced techniques like pair distribution function (PDF) and reverse Monte Carlo simulation (RMC) were used to analyze the atomic structure, revealing that low coordination and tensile strain in palladium sites are key for improving catalytic performance.
Article Abstract
Excellent ethylene selectivity in acetylene semi-hydrogenation is often obtained at the expense of activity. To break the activity-selectivity trade-off, precise control and in-depth understanding of the three-dimensional atomic structure of surfacial active sites are crucial. Here, we designed a novel Au@PdCu core-shell nanocatalyst featuring diluted and stretched Pd sites on the ultrathin shell (1.6 nm), which showed excellent reactivity and selectivity, with 100% acetylene conversion and 92.4% ethylene selectivity at 122 °C, and the corresponding activity was 3.3 times higher than that of the PdCu alloy. The atomic three-dimensional decoding for the activity-selectivity balance was revealed by combining pair distribution function (PDF) and reverse Monte Carlo simulation (RMC). The results demonstrate that a large number of active sites with a low coordination number of Pd-Pd pairs and an average 3.25% tensile strain are distributed on the surface of the nanocatalyst, which perform a pivotal function in the simultaneous improvement of hydrogenation activity and ethylene selectivity. Our work not only develops a novel strategy for unlocking the linear scaling relation in heterogeneous catalysis but also provides a paradigm for atomic 3D understanding of lattice strain in core-shell nanocatalysts.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11290329 | PMC |
| http://dx.doi.org/10.1039/d4sc03291h | DOI Listing |
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