Hydrophilic Ti-MWW for catalyzing epoxidation of allyl alcohol

Xianchen Gong; Jie Tuo; Jilong Wang; Xintong Li; Chengwei Zhai; Hao Xu; Peng Wu

doi:10.20517/cs.2023.59

Chemical Synthesis ›› 2024, Vol. 4 ›› Issue (1) :14 DOI: 10.20517/cs.2023.59

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Hydrophilic Ti-MWW for catalyzing epoxidation of allyl alcohol

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Abstract

Titanosilicates are widely applied in the alkene epoxidation reactions with high reaction rate and selectivity to desired products. Their catalytic performance depends on the structure topology, the micro-environment of Ti active sites, and the hydrophobicity/hydrophilicity of zeolite framework. Herein, we focus on a hydrophilic substrate of allyl alcohol (AAL) and investigated catalytic performance of four titanosilicates (TS-1, Ti-MOR, Ti-MWW, and Re-Ti-MWW) in the AAL epoxidation reaction with hydrogen peroxide as the oxidant. Among them, Re-Ti-MWW, synthesized via the post-modification of Ti-MWW with piperidine, exhibited the highest activity. Moreover, the preferred solvent changed from MeCN for Ti-MWW to H₂O for Re-Ti-MWW. The relative diffusion rate of AAL over Re-Ti-MWW was up to 466 × 10^-7 s^-1, much larger than those of other zeolites. The higher diffusion rate of Re-Ti-MWW was probably derived from the higher framework hydrophilicity as revealed by the smaller water contact angle of Re-Ti-MWW compared to the other zeolites, which contributed to the high activity in AAL epoxidation. In the continuous slurry reactor, Re-Ti-MWW achieved a high catalytic lifetime of 163 h, with the selectivity of desirable glycidol product maintained at > 97% in the H₂O solvent system, showing high potential as an industrial catalyst for the AAL epoxidation reaction.

Keywords

Titanosilicates / Ti-MWW zeolite / allyl alcohol epoxidation / hydrophilic / diffusion rate

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Xianchen Gong, Jie Tuo, Jilong Wang, Xintong Li, Chengwei Zhai, Hao Xu, Peng Wu. Hydrophilic Ti-MWW for catalyzing epoxidation of allyl alcohol. Chemical Synthesis, 2024, 4(1): 14 DOI:10.20517/cs.2023.59

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