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Mechanism driven design of trimer Ni1Sb2 site delivering superior hydrogenation selectivity to ethylene

Xiaohu Ge, Mingying Dou, Yueqiang Cao, Xi Liu, Qiang Yuwen, Jing Zhang, Gang Qian, Xue‐Qing Gong, Xinggui Zhou, Liwei Chen, Weikang Yuan, Xuezhi Duan

2022Nature Communications74 citationsDOIOpen Access PDF

Abstract

Abstract Mechanism driven catalyst design with atomically uniform ensemble sites is an important yet challenging issue in heterogeneous catalysis associated with breaking the activity-selectivity trade-off. Herein, a trimer Ni 1 Sb 2 site in NiSb intermetallic featuring superior selectivity is elaborated for acetylene semi-hydrogenation via a theoretical guidance with a precise synthesis strategy. The trimer Ni 1 Sb 2 site in NiSb intermetallic is predicted to endow acetylene reactant with an adequately but not excessively strong σ-adsorption mode while ethylene product with a weak π-adsorption one, where such compromise delivers higher ethylene formation rate. An in-situ trapping of molten Sb by Ni strategy is developed to realize the construction of Ni 1 Sb 2 site in the intermetallic P6 3 /mmc NiSb catalysts. Such catalyst exhibits ethylene selectivity up to 93.2% at 100% of acetylene conversion, significantly prevailing over the referred Ni catalyst. These insights shed new lights on rational catalyst design by taming active sites to energetically match targeted reaction pathway.

Topics & Concepts

TrimerMechanism (biology)SelectivityEthyleneChemistryPhotochemistryCombinatorial chemistryNanotechnologyCatalysisMaterials scienceOrganic chemistryPhysicsDimerQuantum mechanicsElectrocatalysts for Energy ConversionCatalytic Processes in Materials ScienceAmmonia Synthesis and Nitrogen Reduction
Mechanism driven design of trimer Ni1Sb2 site delivering superior hydrogenation selectivity to ethylene | Litcius