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Evolution of a Metal‐Organic Framework into a Brønsted Acid Catalyst for Glycerol Dehydration to Acrolein

Xiaomin Li, Liang Huang, Alena Kochubei, Jun Huang, Wei Shen, Hualong Xu, Qiaowei Li

2020ChemSusChem46 citationsDOI

Abstract

Abstract Metal−organic frameworks (MOFs) as solid acid catalysts provide active sites with definite structures. Here, Zr 6 ‐based MOF‐808 and its derivatives were studied as catalysts for glycerol dehydration, the products of which (acrolein vs. acetol) are very sensitive to the nature of the catalytic acid sites. Evolving MOF‐808 into MOF‐808‐S with a 120 % increase in the number of Brønsted OH − /H 2 O coordinated to Zr IV and a vanished Lewis acidity by steam treatment, the post‐synthetically modified catalyst presented 100 % conversion of glycerol, 91 % selectivity to acrolein, and 0 % selectivity to acetol within the active window. Real‐time analysis of the product composition indicated the in situ MOF structural evolution. Overall, the specific MOF‐substrate interaction characterized by the probe reaction provides more understandings on the structural evolution of the MOFs and their impact on the performance as solid acid catalysts.

Topics & Concepts

AcroleinCatalysisBrønsted–Lowry acid–base theorySelectivityChemistryLewis acids and basesMetal-organic frameworkGlycerolSynergistic catalysisHeterogeneous catalysisDehydrationOrganic chemistryAdsorptionBiochemistryMetal-Organic Frameworks: Synthesis and ApplicationsCarbon dioxide utilization in catalysisCatalysis for Biomass Conversion
Evolution of a Metal‐Organic Framework into a Brønsted Acid Catalyst for Glycerol Dehydration to Acrolein | Litcius