A kinetic study of the photoinduced oxo-transfer using a Mo complex anchored to TiO2

Julián E. Sánchez-Velandia; Edgar A. Páez-Mozo; Fernando Martínez-Ortega

doi:10.17533/udea.redin.20200477

Authors

Julián E. Sánchez-Velandia Industrial University of Santander
Edgar A. Páez-Mozo Industrial University of Santander
Fernando Martínez-Ortega Industrial University of Santander

DOI:

https://doi.org/10.17533/udea.redin.20200477

Keywords:

photonic flux, selective photooxidation , dioxomolybdenum complex, quantum yield

Abstract

Kinetic study of the photo-assisted oxygen atom transfer reaction (OAT) using a dioxo-Mo complex anchored on TiO₂, stimulated by light, was performed at ambient conditions using triphenylphosphine (PPh₃) as a model molecule. The kinetic of the OAT reaction was studied with three catalytic systems: 4,4’-dicarboxylate-2,2’-bipyridine-dioxochloromolybdenum (MoO₂L/TiO₂), H₂MoO₄ (H₂MoO₄/TiO₂) and molybdenum oxide (MoO₃/ TiO₂) anchored to TiO₂. The MoO₂L/TiO₂ gives conversion higher than 90% and selectivity (to phosphine oxide) close to 100%. MoO₃/TiO₂ did not allow the oxo-transference, suggesting the importance of the bipyridine ligand as an electronic connector between MoO₂L unit and TiO₂. With the MoO₂L/TiO₂ system was observed that when the photonic flux increases, the quantum yield, and the OAT reaction rate increases.

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Author Biographies

Julián E. Sánchez-Velandia, Industrial University of Santander

Center for Research in Catalysis, School of Chemistry, Faculty of Sciences.

Edgar A. Páez-Mozo, Industrial University of Santander

Center for Research in Catalysis, School of Chemistry, Faculty of Sciences.

Fernando Martínez-Ortega, Industrial University of Santander

Center for Research in Catalysis, School of Chemistry, Faculty of Sciences.

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