Selective hydrogenation of phenol to cyclohexanone over Pd nanoparticles encaged hollow mesoporous silica catalytic nanoreactors

Pd nanoparticles (NPs) encaged hollow mesoporous silica nanoreactors (Pd@HMSNs) are prepared for hydrogenations of phenol, cresols and chlorophenols to cyclohexanone derivatives. Pd@HMSNs feature - 4 nm Pd NPs in similar to 16 nm hollow cavities of similar to 30 nm HMSNs. Such Pd@HMSNs are highly thermally and catalytically stable. At mild reaction conditions, Pd@HMSNs efficiently catalyze hydrogenations of phenol and m-cresol to cyclohexanone derivatives with >= 98.3 % selectivity at >= 99.0 % conversions. Hydrogenations of o- and m-chlorophenol over Pd@HMSNs give cyclohexanone with >= 97.3 % selectivity at 100.0 % conversions, demonstrating a beneficial effect of such HMSNs for consecutive reactions. The confinement of Pd NPs inside hollow cavities of mesoporous nanoreactors greatly promotes collision times of reactant molecules with Pd NPs, resulting in an enhanced catalytic efficiency, while the residence of Pd NPs inside cavities provides a protecting effect for Pd NPs and is beneficial to thermal and catalytic stabilities.

Automated summary

Pd nanoparticles encaged hollow mesoporous silica nanoreactors (Pd@HMSNs) are efficiently prepared for hydrogenations of phenol, cresols and chlorophenols to cyclohexanone derivatives under mild reaction conditions. The Pd@HMSNs exhibit excellent thermal and catalytic stabilities, with the confinement of Pd NPs inside hollow cavities greatly enhancing catalytic efficiency.