Efficient Catalytic Upgrade of Fructose to Alkyl Levulinates with Phenylpyridine- phosphotungstate Solid Hybrids

Author(s): Chengjiang Fang, Yan Li, Zhaozhuo Yu, Hu Li*, Song Yang*.

Journal Name: Current Green Chemistry

Volume 6 , Issue 1 , 2019

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Abstract:

Biomass, as the most abundant and renewable organic carbon source, can be upgraded into various value-added platform molecules. To implement more sustainable and economic catalytic biomass valorization, reusable heterogeneous catalysts would be one of the preferable choices. In this work, a series of phosphotungstic acid-based solid hybrids were produced by assembly of phosphotungstic acid with different pyridines using a facile solvothermal method. The obtained 3- phenylpyridine-phosphotungstate hybrid displayed superior catalytic performance in the upgrade of fructose to methyl levulinate with 71.2% yield and 83.2% fructose conversion at 140 ºC for 8 h in methanol, a bio-based and environmentally friendly solvent, which was probably due to its relatively large pore size and high hydrophobicity. This low-cost and eco-friendly catalytic process could be simply operated in a single pot without cumbersome separation steps. In addition, the 3- phenylpyridine-phosphotungstate catalyst was able to be reused for four times with little deactivation.

Keywords: Biomass conversion, biofuel, alkyl levulinate, inorganic-organic hybrid, heterogeneous catalysis, green chemistry.

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Article Details

VOLUME: 6
ISSUE: 1
Year: 2019
Page: [44 - 52]
Pages: 9
DOI: 10.2174/2213346105666181112112330

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