Hemicellulose degradation upon hydrothermal treatment of black liquor

Maitz, Silvia; Lanz, Julia; Siebenhofer, Matthäus; Kienberger, Marlene

doi:10.34726/609

DC Field

Value

Language

dc.contributor.author

Maitz, Silvia

dc.contributor.author

Lanz, Julia

dc.contributor.author

Siebenhofer, Matthäus

dc.contributor.author

Kienberger, Marlene

dc.contributor.editor

Jordan, Christian

dc.date.accessioned

2021-01-15T09:12:51Z

dc.date.available

2021-01-15T09:12:51Z

dc.date.issued

2020-12

dc.identifier.citation

<div class="csl-bib-body"> <div class="csl-entry">Maitz, S., Lanz, J., Siebenhofer, M., & Kienberger, M. (2020). Hemicellulose degradation upon hydrothermal treatment of black liquor. In C. Jordan (Ed.), <i>Proceedings of the 16th Minisymposium Verfahrenstechnik and 7th Partikelforum (TU Wien, Sept. 21/22, 2020)</i> (pp. MoP3-(08) page 1-MoP3-(08) page 4). chemical-engineering.at. https://doi.org/10.34726/609</div> </div>

dc.identifier.uri

http://hdl.handle.net/20.500.12708/16666

dc.identifier.uri

https://doi.org/10.34726/609

dc.description.abstract

Black liquor from Kraft pulping is a very promising feedstock for isolation of bio-based platform chemicals. As a pre-treatment step before fractionation and isolation processes, hydrothermal treatment of black liquor can be beneficial to improve the processability of the liquor and fine-tune its composition. In the present study, we present the results of black liquor heat treatment experiments and show that the hemicelluloses can be completely degraded upon treatment at 220 °C for 2 h.

dc.language.iso

dc.rights.uri

http://creativecommons.org/licenses/by/4.0/

dc.subject

black liquor

dc.subject

hydrothermal treatment

dc.subject

hemicellulose degradation

dc.title

Hemicellulose degradation upon hydrothermal treatment of black liquor

dc.type

Inproceedings

dc.type

Konferenzbeitrag

dc.rights.license

Creative Commons Namensnennung 4.0 International

dc.rights.license

Creative Commons Attribution 4.0 International

dc.identifier.doi

10.34726/609

dc.contributor.affiliation

Graz University of Technology, Austria

dc.contributor.affiliation

Graz University of Technology, Austria

dc.contributor.affiliation

Graz University of Technology, Austria

dc.contributor.affiliation

Graz University of Technology, Austria

dc.relation.isbn

978-3-903337-01-5

dc.relation.doi

10.34726/541

dc.description.startpage

MoP3-(08) page 1

dc.description.endpage

MoP3-(08) page 4

dcterms.dateSubmitted

2020-03-01

dc.type.category

Full-Paper Contribution

tuw.booktitle

Proceedings of the 16th Minisymposium Verfahrenstechnik and 7th Partikelforum (TU Wien, Sept. 21/22, 2020)

tuw.relation.ispartof

10.34726/541

tuw.relation.publisher

chemical-engineering.at

tuw.relation.publisherplace

Wien

tuw.version

vor

tuw.linking

http://www.chemical-engineering.at/minisymposium/proc/2020/MoP3_08.pdf

tuw.publication.orgunit

E166-02-2 - Forschungsgruppe Fluiddynamische Simulation (CFD)

dc.identifier.libraryid

AC17202289

dc.description.numberOfPages

dc.rights.identifier

CC BY 4.0

dc.rights.identifier

CC BY 4.0

tuw.editor.orcid

0000-0002-9661-0959

item.openairetype

conference paper

item.languageiso639-1

item.cerifentitytype

Publications

item.mimetype

application/pdf

item.fulltext

with Fulltext

item.openaccessfulltext

Open Access

item.grantfulltext

open

item.openairecristype

http://purl.org/coar/resource_type/c_5794

crisitem.author.dept

Graz University of Technology

crisitem.author.dept

Graz University of Technology

crisitem.author.dept

Graz University of Technology

crisitem.author.dept

Graz University of Technology

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