Abstract
Cyclohexanone and its derivatives are very important chemicals, which are currently produced mainly by oxidation of cyclohexane or alkylcyclohexane, hydrogenation of phenols, and alkylation of cyclohexanone. Here we report that bromide salt-modified Pd/C in H2O/CH2Cl2 can efficiently catalyse the transformation of aromatic ethers, which can be derived from biomass, to cyclohexanone and its derivatives via hydrogenation and hydrolysis processes. The yield of cyclohexanone from anisole can reach 96%, and the yields of cyclohexanone derivatives produced from the aromatic ethers, which can be extracted from plants or derived from lignin, are also satisfactory. Detailed study shows that the Pd, bromide salt and H2O/CH2Cl2 work cooperatively to promote the desired reaction and inhibit the side reaction. Thus high yields of desired products can be obtained. This work opens the way for production of ketones from aromatic ethers that can be derived from biomass.
Highlights
Cyclohexanone and its derivatives are very important chemicals, which are currently produced mainly by oxidation of cyclohexane or alkylcyclohexane, hydrogenation of phenols, and alkylation of cyclohexanone
It was discovered that bromide salt modified Pd/C (m-Pd/C) catalyst in H2O/CH2Cl2 medium was highly efficient for the transformation of aromatic ethers to ketones, and the yield of cyclohexanone could reach 96% for the conversion of anisole to cyclohexanone
We first used anisole to study the conversion of aromatic ethers to cyclohexanone and its derivatives because it has only one methoxy group that simplifies the study of the reaction
Summary
Cyclohexanone and its derivatives are very important chemicals, which are currently produced mainly by oxidation of cyclohexane or alkylcyclohexane, hydrogenation of phenols, and alkylation of cyclohexanone. It was discovered that bromide salt modified Pd/C (m-Pd/C) catalyst in H2O/CH2Cl2 medium was highly efficient for the transformation of aromatic ethers to ketones, and the yield of cyclohexanone could reach 96% for the conversion of anisole to cyclohexanone. This catalytic system could be applied to transform other aromatic ethers to ketones with high yields. This work opens the way for sustainable producing ketones from bio-based feedstocks
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