Lignin Extraction and Condensation as a Function of Temperature, Residence Time, and Solvent System in Flow-through Reactors

Author(s)

Brandner, David G; Gracia Vitoria, Jaime; Kenny, Jacob K; Bussard, Jeremy R; Jang, Jun Hee; Woodworth, Sean P; Vanbroekhoven, Karolien; Román-Leshkov, Yuriy; Beckham, Gregg T; ... Show more Show less

Abstract

Solvolytic extraction of lignin from biomass is a critical step in lignin-first biorefining, including the reductive catalytic fractionation (RCF) process. Key to optimal RCF processing is the ability to rapidly extract lignin from biomass at high delignification extents and transfer the lignin molecules to a catalyst surface in a time frame that minimizes lignin condensation reactions. Here, we use a flow-through reactor to study the effects of temperature (175-250 °C), residence time (9 to 36 min), and solvent composition (methanol and methanol-water) on lignin extraction and condensation. We evaluated three metrics at each condition: total delignification, delignification rate, and extent of condensation, the latter measured by a decrease in monomer yield for batch hydrogenolysis reactions of solvolysis liquor compared to batch RCF reactions. We observe that delignification is predominantly determined by temperature, while residence time dictates the lignin condensation extent. Moreover, the extent of both extraction and condensation increased in the methanol-water solvent system compared to that in the methanol system. Lignin extracted in methanol is stable up to 18-min residence times at or below 225 °C, while a majority of the lignin extracted in methanol-water is condensed with a 9-min residence time at 200 °C. These results can inform reactor designs and solvent selection for lignin-first biorefining processes that aim to physically separate the biomass and catalyst.

Date issued

2025-08-01

URI

https://hdl.handle.net/1721.1/164066

Journal

ACS Sustainable Chemistry & Engineering

Publisher

American Chemical Society

Citation

David G. Brandner, Jaime Gracia Vitoria, Jacob K. Kenny, Jeremy R. Bussard, Jun Hee Jang, Sean P. Woodworth, Karolien Vanbroekhoven, Yuriy Román-Leshkov, and Gregg T. Beckham. ACS Sustainable Chemistry & Engineering 2025 13 (31), 12573-12582.

Version: Final published version