Synergistic Effect Enhancing Baeyer‐Villiger Oxidation Performance of Resin‐Derived‐Carbon Supported FeCe Bimetallic Catalyst

Abstract Upgrading cyclohexanone to ϵ‐caprolactone (ϵ‐CL) is of great importance to the synthesis of high value‐added downstream chemicals and the reduction of foam plastic. The catalytic synthesis of ϵ‐CL from cyclohexanone through O 2 /aldehyde method is an environmentally benign one‐pot tandem re...

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Bibliographic Details
Published inChemCatChem Vol. 15; no. 21
Main Authors Liu, Mengyang, Gu, Bin, Li, Jingmei, Wei, Huangzhao, Xue, Weiyang, Jiang, Yukun, Sun, Chenglin
Format Journal Article
LanguageEnglish
Published Weinheim Wiley Subscription Services, Inc 08.11.2023
Subjects
Aldehydes
Benzaldehyde
Bimetals
Carbon
Cascade chemical reactions
Catalysts
Chemical synthesis
Cyclohexanone
Dispersion
Free radicals
High temperature
Iron
Oxidation
Peracids
Resins
Self-assembly
Solvents
Synergistic effect
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Summary:Abstract Upgrading cyclohexanone to ϵ‐caprolactone (ϵ‐CL) is of great importance to the synthesis of high value‐added downstream chemicals and the reduction of foam plastic. The catalytic synthesis of ϵ‐CL from cyclohexanone through O 2 /aldehyde method is an environmentally benign one‐pot tandem reaction without using peroxy acid, balancing the requirements of safety and efficiency. However, due to lack of elaborate design and collaboration of multiple active sites for catalysts, the catalytic efficiency of O 2 /aldehyde method still remains to be improved. Herein, a pitaya‐like catalyst (CeFe@RDC‐3) with Ce and Fe highly dispersed on resin‐derived‐carbon is synthesized through high temperature self‐assembly. On this bimetallic catalyst, high yield (97 %) of ϵ‐CL is achieved through aerobic oxidation of cyclohexanone with only 1.5 equivalent benzaldehyde. Moreover, considerable yields of ϵ‐CL, 88.3 % and 74.7 %, respectively, are also obtained over CeFe@RDC‐3 with green solvent (EtOAc) or even without solvent. No loss of activity is observed after five successive cycles, demonstrating high stability of CeFe@RDC‐3. The mechanism study reveals that the high performance of CeFe@RDC‐3 is ascribed to the Ce−Fe bimetallic synergy, uniform metal dispersion, abundant active oxygen and stabilizing effect of resin‐derived‐carbon to free radicals. This work provides prospect for a green, safe and low‐cost strategy for Baeyer‐Villiger process.
ISSN:1867-3880
1867-3899
DOI:10.1002/cctc.202300852