Details

Autor(en) / Beteiligte

• Behloul, Sarah
• Gayraud, Oscar
• Frapper, Gilles
• Guégan, Frédéric
• Upitak, Kanokon
• Thomas, Christophe M.
• Yan, Z.
• De Oliveira Vigier, Karine
• Jérôme, François

Titel

Acid‐Catalyzed Activation and Condensation of the =C5H Bond of Furfural on Aldehydes, an Entry Point to Biobased Monomers

Ist Teil von

• ChemSusChem, 2024-05, Vol.17 (10), p.e202400289-n/a

Ort / Verlag

Germany: Wiley Subscription Services, Inc

Erscheinungsjahr

2024

Quelle

Wiley Online Library

Beschreibungen/Notizen

• Furfural is an industrially relevant biobased chemical platform. Unlike classical furan, or C‐alkylated furans, which have been previously described in the current literature, the =C5H bond of furfural is unreactive. As a result, on a large scale, C=C and C=O bond hydrogenation/hydrogenolysis is mainly performed, with furfuryl alcohol and methyl tetrahydrofuran being the two main downstream chemicals. Here, we show that the derivatization of the ‐CHO group of furfural restores the reactivity of its =C5H bond, thus permitting its double condensation on various alkyl aldehydes. Overcoming the recalcitrance of the =C5H bond of furfural has opened an access to a biobased monomer, whose potential have been investigated in the fabrication of renewably‐sourced poly(silylether). By means of a combined theoretical‐experimental study, a reactivity scale for furfural and its protected derivatives against carbonylated compounds has been established using an electrophilicity descriptor, a means to predict the molecular diversity and complexity this pathway may support, and also to de‐risk any project related to this topic. Finally, by using performance criteria for industrial operations in the field of fuels and commodities, we discussed the industrial potential of this work in terms of cost, E‐factor, reactor productivity and catalyst consumption. By means of a combined theoretical‐experimental study, we unlocked the recalcitrance of the =C5H bond of furfural, paving the way to readily polymerizable biobased building blocks. A reactivity scale for the =C5H bond of furfural, and its derivatives, has been established using an electrophilicity descriptor, a means to predict the molecular diversity and complexity this pathway may support.