Black Bioinks from Superstructured Carbonized Lignin Particles

Bruno D. Mattos; Noora Jäntti; Sergei Khakalo; Ya Zhu; Arttu Miettinen; Joni Parkkonen; Alexey Khakalo; Orlando J. Rojas; Mariko Ago

doi:10.1002/adfm.202304867

Black Bioinks from Superstructured Carbonized Lignin Particles

Bruno D. Mattos^*
, Noora Jäntti
, Sergei Khakalo
, Ya Zhu
, Arttu Miettinen
, Joni Parkkonen
, Alexey Khakalo
, Orlando J. Rojas^*
, Mariko Ago^*

^*Corresponding author for this work

BA5502 ProperTune ICME

Aalto University
University of Jyväskylä
University of British Columbia
Tokyo University of Agriculture and Technology

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

20 Citations (Scopus)

Abstract

A renewable source of carbon black is introduced by the processing of lignin from agro-forestry residues. Lignin side streams are converted into spherical particles by direct aerosolization followed by carbonization. The obtained submicron black carbon is combined with cellulose nanofibers, which act as a binder and rheology modifier, resulting in a new type of colloidal bioink. The bioinks are tested in handwriting and direct ink writing. After consolidation, the black bioinks display total light reflectance (%R) at least three times lower than commercial black inks (reduction from 12 to 4%R). A loading of up to 20% of nanofibers positively affects the cohesion of the dried bioink (1 to 16 MPa), with no significant reduction in light reflectance. This is a result of the superstructuring of the ink components, which disrupts particle packing, intensifies colloidal interactions, introduces light absorption, and non-reflective multiple scattering.

Original language	English
Article number	2304867
Journal	Advanced Functional Materials
Volume	33
Issue number	45
DOIs	https://doi.org/10.1002/adfm.202304867
Publication status	Published - 2 Nov 2023
MoE publication type	A1 Journal article-refereed

Funding

The authors acknowledge funding support from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation program (grant agreement no. 788489, “BioElCell”), the Canada Excellence Research Chair Program (CERC‐2018‐00006). This work was a part of the Academy of Finland's Flagship Programme under Project No. 318890 and 318891 (Competence Center for Materials Bioeconomy, FinnCERES.

Keywords

carbon materials
carbonization
cellulose nanofibers
coatings
particle networks
pigments

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10.1002/adfm.202304867Licence: CC BY

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title = "Black Bioinks from Superstructured Carbonized Lignin Particles",

abstract = "A renewable source of carbon black is introduced by the processing of lignin from agro-forestry residues. Lignin side streams are converted into spherical particles by direct aerosolization followed by carbonization. The obtained submicron black carbon is combined with cellulose nanofibers, which act as a binder and rheology modifier, resulting in a new type of colloidal bioink. The bioinks are tested in handwriting and direct ink writing. After consolidation, the black bioinks display total light reflectance (\%R) at least three times lower than commercial black inks (reduction from 12 to 4\%R). A loading of up to 20\% of nanofibers positively affects the cohesion of the dried bioink (1 to 16 MPa), with no significant reduction in light reflectance. This is a result of the superstructuring of the ink components, which disrupts particle packing, intensifies colloidal interactions, introduces light absorption, and non-reflective multiple scattering.",

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T1 - Black Bioinks from Superstructured Carbonized Lignin Particles

AU - Mattos, Bruno D.

AU - Jäntti, Noora

AU - Khakalo, Sergei

AU - Zhu, Ya

AU - Miettinen, Arttu

AU - Parkkonen, Joni

AU - Khakalo, Alexey

AU - Rojas, Orlando J.

AU - Ago, Mariko

PY - 2023/11/2

Y1 - 2023/11/2

N2 - A renewable source of carbon black is introduced by the processing of lignin from agro-forestry residues. Lignin side streams are converted into spherical particles by direct aerosolization followed by carbonization. The obtained submicron black carbon is combined with cellulose nanofibers, which act as a binder and rheology modifier, resulting in a new type of colloidal bioink. The bioinks are tested in handwriting and direct ink writing. After consolidation, the black bioinks display total light reflectance (%R) at least three times lower than commercial black inks (reduction from 12 to 4%R). A loading of up to 20% of nanofibers positively affects the cohesion of the dried bioink (1 to 16 MPa), with no significant reduction in light reflectance. This is a result of the superstructuring of the ink components, which disrupts particle packing, intensifies colloidal interactions, introduces light absorption, and non-reflective multiple scattering.

AB - A renewable source of carbon black is introduced by the processing of lignin from agro-forestry residues. Lignin side streams are converted into spherical particles by direct aerosolization followed by carbonization. The obtained submicron black carbon is combined with cellulose nanofibers, which act as a binder and rheology modifier, resulting in a new type of colloidal bioink. The bioinks are tested in handwriting and direct ink writing. After consolidation, the black bioinks display total light reflectance (%R) at least three times lower than commercial black inks (reduction from 12 to 4%R). A loading of up to 20% of nanofibers positively affects the cohesion of the dried bioink (1 to 16 MPa), with no significant reduction in light reflectance. This is a result of the superstructuring of the ink components, which disrupts particle packing, intensifies colloidal interactions, introduces light absorption, and non-reflective multiple scattering.

KW - carbon materials

KW - carbonization

KW - cellulose nanofibers

KW - coatings

KW - particle networks

KW - pigments

UR - https://www.scopus.com/pages/publications/85163838557

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DO - 10.1002/adfm.202304867

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VL - 33

JO - Advanced Functional Materials

JF - Advanced Functional Materials

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M1 - 2304867

ER -

Black Bioinks from Superstructured Carbonized Lignin Particles

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Keywords

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