Electrochemical Coupling of Biomass-Derived Acids: New C Platforms for Renewable Polymers and Fuels

Overview

Journal ChemSusChem

Specialty Chemistry

Date 2016 Nov 23

PMID 27873475

Citations 7

Authors

Linglin Wu

Mark Mascal

Thomas J Farmer

Sacha Perocheau Arnaud

Maria-Angelica Wong Chang

Affiliations

Soon will be listed here.

Abstract

Electrolysis of biomass-derived carbonyl compounds is an alternative to condensation chemistry for supplying products with chain length >C for biofuels and renewable materials production. Kolbe coupling of biomass-derived levulinic acid is used to obtain 2,7-octanedione, a new platform molecule only two low process-intensity steps removed from raw biomass. Hydrogenation to 2,7-octanediol provides a chiral secondary diol largely unknown to polymer chemistry, whereas intramolecular aldol condensation followed by hydrogenation yields branched cycloalkanes suitable for use as high-octane, cellulosic gasoline. Analogous electrolysis of an itaconic acid-derived methylsuccinic monoester yields a chiral 2,5-dimethyladipic acid diester, another underutilized monomer owing to lack of availability.

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