Efficient hydrogenolysis of aryl ethers over Ce-MOF supported Pd NPs under mild conditions: mechanistic insight using density functional theoretical calculations

Selective hydrogenolysis of lignin-derived aryl ethers under mild temperature and pressure conditions is an important milestone to be achieved to fulfill the future fuel demands from abundantly available biomass resources. Selective hydrogenolysis requires precise modulation of surface active sites...

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Bibliographic Details
Published in:Catalysis science & technology 2020-10, Vol.1 (2), p.6892-691
Main Authors: Kar, Ashish Kumar, Kaur, Surinder Pal, Kumar, T. J. Dhilip, Srivastava, Rajendra
Format: Article
Language:English
Subjects:
Adsorption
Aromatic compounds
Benzyl phenyl ether
Catalysts
Cerium oxides
Chemical synthesis
Density
Ethers
Hydrogenolysis
Low temperature
Mathematical analysis
Metal-organic frameworks
Nanoparticles
Palladium
Phenols
Photoelectrons
Recyclability
Selectivity
Spectrum analysis
Toluene
X ray photoelectron spectroscopy
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Summary:Selective hydrogenolysis of lignin-derived aryl ethers under mild temperature and pressure conditions is an important milestone to be achieved to fulfill the future fuel demands from abundantly available biomass resources. Selective hydrogenolysis requires precise modulation of surface active sites of the catalyst to obtain the desired activity and selectivity. In this study, the selective hydrogenolysis of benzyl phenyl ether to phenol and toluene is achieved in methanol and water medium at a very low temperature and low H 2 pressure over a Pd nanoparticle decorated Ce-BTC metal-organic framework. The activity of the developed catalyst is two times higher than that of Pd decorated CeO 2 . The structure-activity relationship is established using catalytic measurements, X-ray photoelectron spectroscopy, and transmission electron microscopy. The mechanistic insight into the hydrogenolysis of aryl ethers and the reasons behind the superior activity of Pd/Ce-BTC to that of Pd/CeO 2 are investigated using density functional theoretical (DFT) calculations. Spectroscopic measurements and DFT calculations suggest that the higher Pd 0 /Pd 2+ ratio and higher adsorption of benzyl phenyl ether over Pd/Ce-BTC and the higher adsorption of phenol over Pd/CeO 2 are factors responsible for the higher activity of Pd/Ce-BTC than that of Pd/CeO 2 . Efficient recyclability and hot filtration tests reveal that the catalyst exhibits no noteworthy loss in the activity after five consecutive cycles. The Pd/Ce-BTC catalyst displays a very high turnover frequency and low activation energy, which are very attractive from the industrial perspective and academic point of view. The significant Pd 0 content and optimum bonding of the reactant & product (higher adsorption energy of benzyl phenyl ether and lower desorption energy for phenol) are responsible for the exceptional catalytic activity of Pd/Ce-MOF.
ISSN:2044-4753
2044-4761
DOI:10.1039/d0cy01279c