Isolation of β-O-4-Rich Lignin From Birch in High Yields Enabled by Continuous-Flow Supercritical Water Treatment

Davide Rigo; Tijana Fechter; Ewellyn A. Capanema; Daryna Diment; Marie Alopaeus; Dmitry Tarasov; Danilo Cantero; Mikhail Yu Balakshin

doi:10.1002/cssc.202401683

Isolation of β-O-4-Rich Lignin From Birch in High Yields Enabled by Continuous-Flow Supercritical Water Treatment

Davide Rigo^*
, Tijana Fechter
, Ewellyn A. Capanema^*
, Daryna Diment
, Marie Alopaeus
, Dmitry Tarasov
, Danilo Cantero
, Mikhail Yu Balakshin

^*Corresponding author for this work

Laboratory of Natural Materials Technology

Research output: Contribution to journal › Article › Scientific › peer-review

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Abstract

The continuous flow supercritical water (scH ₂O) treatment of Birch wood (T=372–382 °C; t=0.3–0.7 s; p=260 bar) followed by alkali extraction of lignin allowed for the isolation of lignin and lignin carbohydrate complexes (LCCs) with a high number of β-O-4 moieties in the range 29–57/100 Ar (evaluated by quantitative ¹³C NMR analysis) in yields ranging between 13–19 wt % with respect to the initial wood. A “lightning rod effect” of carbohydrates has been claimed to explain the low degradation of β-O-4 bonds during the process. The structure of the isolated lignin was thoroughly elucidated via comprehensive NMR studies (HSQC, ¹³C and ³¹P). A low degree of condensation (DC)<5 % was found for all the lignin samples, which was only slightly dependent on the reaction severity. The number of aliphatic −OH, phenolic −OH, and −COOH groups was in the range 3.37–5.25, 1.41–2.31 and 0.39–0.73 mmol/g, respectively. The number of −COOH groups increased with increased severity, suggesting that oxidation can occur during the scH ₂O treatment. Furthermore, by simply varying the reaction severity, it was possible to tune important lignin properties, like the molar mass and the glass transition temperature (T _g).

Original language	English
Article number	e202401683
Journal	ChemSusChem
Volume	18
Issue number	1
DOIs	https://doi.org/10.1002/cssc.202401683
Publication status	Published - 2 Jan 2025
MoE publication type	A1 Journal article-refereed

Funding

This work is dedicated to Prof. of practice Dr. Mikhail Balakshin. Prof. Chunlin Xu is thankfully acknowledged for his help in the data discussion. The authors acknowledge the Agencia Estatal de Investigaci\u00F3n for the financial support given in Project PID2020\u2013119249RA\u2212I00. This work was supported by the Regional Government of Castilla y Le\u00F3n (Spain) and the EU-FEDER program (CLU-2019-04). D.C. is funded by the Spanish Ministry of Science, Innovation and Universities (\u201CBeatriz Galindo\u201D fellowship BEAGAL18/00247). D.R., D.D. and M.B gratefully acknowledge the support from the Research Council of Finland (former Academy of Finland, grant decision number 341586). In addition, this work was a part of the Academy of Finland\u2032s Flagship Programme under Projects No. 318890 and 318891 (Competence Center for Materials Bioeconomy, FinnCERES). This work is dedicated to Prof. of practice Dr. Mikhail Balakshin. Prof. Chunlin Xu is thankfully acknowledged for his help in the data discussion. The authors acknowledge the Agencia Estatal de Investigaci\u00F3n for the financial support given in Project PID2020\u2013119249RA\u2212I00. This work was supported by the Regional Government of Castilla y Le\u00F3n (Spain) and the EU\u2010FEDER program (CLU\u20102019\u201004). D.C. is funded by the Spanish Ministry of Science, Innovation and Universities (\u201CBeatriz Galindo\u201D fellowship BEAGAL18/00247). D.R., D.D. and M.B gratefully acknowledge the support from the Research Council of Finland (former Academy of Finland, grant decision number 341586). In addition, this work was a part of the Academy of Finland\u2032s Flagship Programme under Projects No. 318890 and 318891 (Competence Center for Materials Bioeconomy, FinnCERES).

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10.1002/cssc.202401683

ChemSusChem - 2024 - Rigo - Isolation of ‐O‐4‐Rich Lignin From Birch in High Yields Enabled by Continuous‐Flow-1Final published version, 2.76 MBLicence: CC BY-NC-ND

https://urn.fi/URN:NBN:fi-fe2025040122714

Åbo Akademi Functional Printing Center
Toivakka, M. (PI), Rosenholm, J. (PI), Anttu, N. (PI), Bobacka, J. (PI), Huynh, T. P. (PI), Peltonen, J. (PI), Wang, X. (PI), Wilen, C.-E. (PI), Xu, C. (PI), Zhang, H. (PI) & Österbacka, R. (PI)
Faculty of Science and Engineering
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title = "Isolation of β-O-4-Rich Lignin From Birch in High Yields Enabled by Continuous-Flow Supercritical Water Treatment",

abstract = "The continuous flow supercritical water (scH 2O) treatment of Birch wood (T=372–382 °C; t=0.3–0.7 s; p=260 bar) followed by alkali extraction of lignin allowed for the isolation of lignin and lignin carbohydrate complexes (LCCs) with a high number of β-O-4 moieties in the range 29–57/100 Ar (evaluated by quantitative 13C NMR analysis) in yields ranging between 13–19 wt \% with respect to the initial wood. A “lightning rod effect” of carbohydrates has been claimed to explain the low degradation of β-O-4 bonds during the process. The structure of the isolated lignin was thoroughly elucidated via comprehensive NMR studies (HSQC, 13C and 31P). A low degree of condensation (DC)<5 \% was found for all the lignin samples, which was only slightly dependent on the reaction severity. The number of aliphatic −OH, phenolic −OH, and −COOH groups was in the range 3.37–5.25, 1.41–2.31 and 0.39–0.73 mmol/g, respectively. The number of −COOH groups increased with increased severity, suggesting that oxidation can occur during the scH 2O treatment. Furthermore, by simply varying the reaction severity, it was possible to tune important lignin properties, like the molar mass and the glass transition temperature (T g).",

keywords = "Lignin, Lignin carbohydrate complexes (LCCs), NMR, Supercritical water, DSC, GPC",

author = "Davide Rigo and Tijana Fechter and Capanema, \{Ewellyn A.\} and Daryna Diment and Marie Alopaeus and Dmitry Tarasov and Danilo Cantero and Balakshin, \{Mikhail Yu\}",

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AU - Rigo, Davide

AU - Fechter, Tijana

AU - Capanema, Ewellyn A.

AU - Diment, Daryna

AU - Alopaeus, Marie

AU - Tarasov, Dmitry

AU - Cantero, Danilo

AU - Balakshin, Mikhail Yu

PY - 2025/1/2

Y1 - 2025/1/2

N2 - The continuous flow supercritical water (scH 2O) treatment of Birch wood (T=372–382 °C; t=0.3–0.7 s; p=260 bar) followed by alkali extraction of lignin allowed for the isolation of lignin and lignin carbohydrate complexes (LCCs) with a high number of β-O-4 moieties in the range 29–57/100 Ar (evaluated by quantitative 13C NMR analysis) in yields ranging between 13–19 wt % with respect to the initial wood. A “lightning rod effect” of carbohydrates has been claimed to explain the low degradation of β-O-4 bonds during the process. The structure of the isolated lignin was thoroughly elucidated via comprehensive NMR studies (HSQC, 13C and 31P). A low degree of condensation (DC)<5 % was found for all the lignin samples, which was only slightly dependent on the reaction severity. The number of aliphatic −OH, phenolic −OH, and −COOH groups was in the range 3.37–5.25, 1.41–2.31 and 0.39–0.73 mmol/g, respectively. The number of −COOH groups increased with increased severity, suggesting that oxidation can occur during the scH 2O treatment. Furthermore, by simply varying the reaction severity, it was possible to tune important lignin properties, like the molar mass and the glass transition temperature (T g).

AB - The continuous flow supercritical water (scH 2O) treatment of Birch wood (T=372–382 °C; t=0.3–0.7 s; p=260 bar) followed by alkali extraction of lignin allowed for the isolation of lignin and lignin carbohydrate complexes (LCCs) with a high number of β-O-4 moieties in the range 29–57/100 Ar (evaluated by quantitative 13C NMR analysis) in yields ranging between 13–19 wt % with respect to the initial wood. A “lightning rod effect” of carbohydrates has been claimed to explain the low degradation of β-O-4 bonds during the process. The structure of the isolated lignin was thoroughly elucidated via comprehensive NMR studies (HSQC, 13C and 31P). A low degree of condensation (DC)<5 % was found for all the lignin samples, which was only slightly dependent on the reaction severity. The number of aliphatic −OH, phenolic −OH, and −COOH groups was in the range 3.37–5.25, 1.41–2.31 and 0.39–0.73 mmol/g, respectively. The number of −COOH groups increased with increased severity, suggesting that oxidation can occur during the scH 2O treatment. Furthermore, by simply varying the reaction severity, it was possible to tune important lignin properties, like the molar mass and the glass transition temperature (T g).

KW - Lignin

KW - Lignin carbohydrate complexes (LCCs)

KW - NMR

KW - Supercritical water

KW - DSC

KW - GPC

U2 - 10.1002/cssc.202401683

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JO - ChemSusChem

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IS - 1

M1 - e202401683

ER -

Isolation of β-O-4-Rich Lignin From Birch in High Yields Enabled by Continuous-Flow Supercritical Water Treatment

Abstract

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