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A combination of experimental and computational methods to study the reactions during a Lignin-First approach

Ivan Kumaniaev, Elena Subbotina, Maxim V. Galkin, Pemikar Srifa, Susanna Monti, Isara Mongkolpichayarak, Duangamol Nuntasri Tungasmita, Joseph S. M. Samec

2020Pure and Applied Chemistry17 citationsDOIOpen Access PDF

Abstract

Abstract Current pulping technologies only valorize the cellulosic fiber giving total yields from biomass below 50 %. Catalytic fractionation enables valorization of both cellulose, lignin, and, optionally, also the hemicellulose. The process consists of two operations occurring in one pot: (1) solvolysis to separate lignin and hemicellulose from cellulose, and (2) transition metal catalyzed reactions to depolymerize lignin and to stabilized monophenolic products. In this article, new insights into the roles of the solvolysis step as well as the operation of the transition metal catalyst are given. By separating the solvolysis and transition metal catalyzed hydrogen transfer reactions in space and time by applying a flow-through set-up, we have been able to study the solvolysis and transition metal catalyzed reactions separately. Interestingly, the solvolysis generates a high amount of monophenolic compounds by pealing off the end groups from the lignin polymer and the main role of the transition metal catalyst is to stabilize these monomers by transfer hydrogenation/hydrogenolysis reactions. The experimental data from the transition metal catalyzed transfer hydrogenation/hydrogenolysis reactions was supported by molecular dynamics simulations using ReaXFF.

Topics & Concepts

SolvolysisChemistryHydrogenolysisLigninHemicelluloseCelluloseCatalysisOrganic chemistryTransition metalHydrolysisLignin and Wood ChemistryCatalysis for Biomass ConversionBiofuel production and bioconversion