posted on 2024-02-09, 09:33authored byXiaohu Ge, Jun Yin, Zhouhong Ren, Kelin Yan, Yundao Jing, Yueqiang Cao, Nina Fei, Xi Liu, Xiaonan Wang, Xinggui Zhou, Liwei Chen, Weikang Yuan, Xuezhi Duan
Alkyne
hydrogenation on palladium-based catalysts modified with
silver is currently used in industry to eliminate trace amounts of
alkynes in alkenes produced from steam cracking and alkane dehydrogenation
processes. Intensive efforts have been devoted to designing an alternative
catalyst for improvement, especially in terms of selectivity and catalyst
cost, which is still far away from that as expected. Here, we describe
an atomic design of a high-performance Ni-based intermetallic catalyst
aided by active machine learning combined with density functional
theory calculations. The engineered NiIn catalyst exhibits >97%
selectivity
to ethylene and propylene at the full conversion of acetylene and
propyne at mild temperature, outperforming the reported Ni-based catalysts
and even noble Pd-based ones. Detailed mechanistic studies using theoretical
calculations and advanced characterizations elucidate that the atomic-level
defined coordination environment of Ni sites and well-designed hybridization
of Ni 3d with In 5p orbital determine
the semihydrogenation pathway.