Expanding lignin thermal property space by fractionation and covalent modification

Luke A. Riddell; Floris J.P.A. Enthoven; Jean Pierre B. Lindner; Florian Meirer; Pieter C.A. Bruijnincx

doi:10.1039/d3gc01055d

Expanding lignin thermal property space by fractionation and covalent modification

Luke A. Riddell, Floris J.P.A. Enthoven, Jean Pierre B. Lindner, Florian Meirer, Pieter C.A. Bruijnincx^*

^*Corresponding author for this work

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

Abstract

To fully exploit kraft lignin's potential in material applications, we need to achieve tight control over those key physicochemical lignin parameters that ultimately determine, and serve as proxy for, the properties of lignin-derived materials. Here, we show that fractionation combined with systematic (incremental) modification provides a powerful strategy to expand and controllably tailor lignin property space. In particular, the glass transition temperature (T_g) of a typical kraft lignin could be tuned over a remarkable and unprecedented 213 °C. Remarkably, for all fractions the T_g proved to be highly linearly correlated with the degree of derivatisation by allylation, offering such tight control over the T_g of the lignin and ultimately the ability to ‘dial-in’ this key property. Importantly, such control over this proxy parameter indeed translated well to lignin-based thiol-ene thermosetting films, whose T_gs thus covered a range from 2-124 °C. This proof of concept suggests this approach to be a powerful and generalisable one, allowing a biorefinery or downstream operation to consciously and reliably tailor lignins to predictable specifications which fit their desired application.

Original language	English
Pages (from-to)	6051-6056
Number of pages	6
Journal	Green Chemistry
Volume	25
Issue number	15
DOIs	https://doi.org/10.1039/d3gc01055d
Publication status	Published - 13 Jul 2023

Bibliographical note

Publisher Copyright:
© 2023 The Royal Society of Chemistry.

Funding

This work was supported by the Netherlands Organisation for Scientific Research (NWO LIFT grant ENPPS.LIFT.019.17), as well as BASF SE. Stora Enso SE is acknowledged for providing the kraft lignin.

Funders	Funder number
BASF
Nederlandse Organisatie voor Wetenschappelijk Onderzoek	ENPPS.LIFT.019.17

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Cite this

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title = "Expanding lignin thermal property space by fractionation and covalent modification",

abstract = "To fully exploit kraft lignin's potential in material applications, we need to achieve tight control over those key physicochemical lignin parameters that ultimately determine, and serve as proxy for, the properties of lignin-derived materials. Here, we show that fractionation combined with systematic (incremental) modification provides a powerful strategy to expand and controllably tailor lignin property space. In particular, the glass transition temperature (Tg) of a typical kraft lignin could be tuned over a remarkable and unprecedented 213 °C. Remarkably, for all fractions the Tg proved to be highly linearly correlated with the degree of derivatisation by allylation, offering such tight control over the Tg of the lignin and ultimately the ability to {\textquoteleft}dial-in{\textquoteright} this key property. Importantly, such control over this proxy parameter indeed translated well to lignin-based thiol-ene thermosetting films, whose Tgs thus covered a range from 2-124 °C. This proof of concept suggests this approach to be a powerful and generalisable one, allowing a biorefinery or downstream operation to consciously and reliably tailor lignins to predictable specifications which fit their desired application.",

author = "Riddell, \{Luke A.\} and Enthoven, \{Floris J.P.A.\} and Lindner, \{Jean Pierre B.\} and Florian Meirer and Bruijnincx, \{Pieter C.A.\}",

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AU - Riddell, Luke A.

AU - Enthoven, Floris J.P.A.

AU - Lindner, Jean Pierre B.

AU - Meirer, Florian

AU - Bruijnincx, Pieter C.A.

PY - 2023/7/13

Y1 - 2023/7/13

N2 - To fully exploit kraft lignin's potential in material applications, we need to achieve tight control over those key physicochemical lignin parameters that ultimately determine, and serve as proxy for, the properties of lignin-derived materials. Here, we show that fractionation combined with systematic (incremental) modification provides a powerful strategy to expand and controllably tailor lignin property space. In particular, the glass transition temperature (Tg) of a typical kraft lignin could be tuned over a remarkable and unprecedented 213 °C. Remarkably, for all fractions the Tg proved to be highly linearly correlated with the degree of derivatisation by allylation, offering such tight control over the Tg of the lignin and ultimately the ability to ‘dial-in’ this key property. Importantly, such control over this proxy parameter indeed translated well to lignin-based thiol-ene thermosetting films, whose Tgs thus covered a range from 2-124 °C. This proof of concept suggests this approach to be a powerful and generalisable one, allowing a biorefinery or downstream operation to consciously and reliably tailor lignins to predictable specifications which fit their desired application.

AB - To fully exploit kraft lignin's potential in material applications, we need to achieve tight control over those key physicochemical lignin parameters that ultimately determine, and serve as proxy for, the properties of lignin-derived materials. Here, we show that fractionation combined with systematic (incremental) modification provides a powerful strategy to expand and controllably tailor lignin property space. In particular, the glass transition temperature (Tg) of a typical kraft lignin could be tuned over a remarkable and unprecedented 213 °C. Remarkably, for all fractions the Tg proved to be highly linearly correlated with the degree of derivatisation by allylation, offering such tight control over the Tg of the lignin and ultimately the ability to ‘dial-in’ this key property. Importantly, such control over this proxy parameter indeed translated well to lignin-based thiol-ene thermosetting films, whose Tgs thus covered a range from 2-124 °C. This proof of concept suggests this approach to be a powerful and generalisable one, allowing a biorefinery or downstream operation to consciously and reliably tailor lignins to predictable specifications which fit their desired application.

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Expanding lignin thermal property space by fractionation and covalent modification

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