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Ambient-condition acetylene hydrogenation to ethylene over WS2-confined atomic Pd sites

Wangwang Zhang, Kelechi Uwakwe, Jingting Hu, Wei Yan, Juntong Zhu, Wu Zhou, Chao Ma, Liang Yu, Rui Huang, Dehui Deng

2024Nature Communications22 citationsDOIOpen Access PDF

Abstract

Ambient-condition acetylene hydrogenation to ethylene (AC-AHE) is a promising process for ethylene production with minimal additional energy input, yet remains a great challenge due to the difficulty in the coactivation of acetylene and H2 at room temperature. Herein, we report a highly efficient AC-AHE process over robust sulfur-confined atomic Pd species on tungsten sulfide surface. The catalyst exhibits over 99% acetylene conversion with a high ethylene selectivity of 70% at 25 oC, and a record space-time yield of ethylene of 1123 molC2H4 molPd−1 h−1 under ambient conditions, which is nearly four times that of the typical Pd1Ag3/Al2O3 catalyst, and exhibiting superior stability of over 500 h. We demonstrate that the confinement of Pd-S coordination induces positively-charged atomic Pdδ+, which not only facilitates C2H2 hydrogenation but also promotes C2H4 desorption, thereby enabling a high conversion of C2H2 to C2H4 at room temperature while suppressing over-hydrogenation to C2H6. Ambient-condition acetylene hydrogenation to ethylene (AC-AHE) is a promising process for ethylene production yet remains a challenge. Here the authors report a highly efficient AC-AHE process over robust sulfur-confined atomic Pd species on tungsten sulfide surface, achieving over 99% conversion and 70% selectivity, with a record-breaking ethylene yield and excellent stability exceeding 500 h at 25 °C.

Topics & Concepts

AcetyleneEthyleneChemistryMaterials scienceCatalysisPhotochemistryOrganic chemistryHybrid Renewable Energy SystemsHydrogen Storage and MaterialsMachine Learning in Materials Science