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Sulfur Poisoning and Self‐Recovery of Single‐Site Rh<sub>1</sub>/Porous Organic Polymer Catalysts for Olefin Hydroformylation

Siquan Feng, Miao Jiang, Xiangen Song, Panzhe Qiao, Li Yan, Yutong Cai, Bin Li, Cunyao Li, Lili Ning, Siyue Liu, Weiqing Zhang, Guorong Wu, Jia‐Yue Yang, Wenrui Dong, Xueming Yang, Zheng Jiang, Yunjie Ding

2023Angewandte Chemie International Edition47 citationsDOIOpen Access PDF

Abstract

Abstract Sulfur poisoning and regeneration are global challenges for metal catalysts even at the ppm level. The sulfur poisoning of single‐metal‐site catalysts and their regeneration is worthy of further study. Herein, sulfur poisoning and self‐recovery are first presented on an industrialized single‐Rh‐site catalyst (Rh 1 /POPs). A decreased turnover frequency of Rh 1 /POPs from 4317 h −1 to 318 h −1 was observed in a 1000 ppm H 2 S co‐feed for ethylene hydroformylation, but it self‐recovered to 4527 h −1 after withdrawal of H 2 S, whereas the rhodium nanoparticles demonstrated poor activity and self‐recovery ability. H 2 S reduced the charge density of the single Rh atom and lowered its Gibbs free energy with the formation of inactive (SH)Rh(CO)(PPh 3 ‐frame) 2 , which could be regenerated to active HRh(CO)(PPh 3 ‐frame) 2 after withdrawing H 2 S. The mechanism and the sulfur‐related structure–activity relationship were highlighted. This work provides an understanding of heterogeneous ethylene hydroformylation and sulfur‐poisoned regeneration in the science of single‐atom catalysts.

Topics & Concepts

HydroformylationOlefin fiberOrganic polymerSulfurCatalysisPolymerPorosityChemistryOrganic chemistryMaterials scienceRhodiumCarbon dioxide utilization in catalysisCatalysis and Hydrodesulfurization StudiesMetal-Organic Frameworks: Synthesis and Applications