Publications by Prof. Gunnar Henriksson
Gunnar Henrikssons
[1]
A. J. Svagan et al.,
"Centrifuge fractionation during purification of cellulose nanocrystals after acid hydrolysis and consequences on their chiral self-assembly,"
Carbohydrate Polymers, vol. 328, 2024.
[2]
P. A. Lindén et al.,
"Adapting the kraft cooking process in glycerol media. Studies of impregnation kinetics,"
Nordic Pulp & Paper Research Journal, vol. 38, no. 1, pp. 9-18, 2023.
[3]
[4]
J. White et al.,
"Glycerol Electrooxidation at Industrially Relevant Current Densities Using Electrodeposited PdNi/Nifoam Catalysts in Aerated Alkaline Media,"
Journal of the Electrochemical Society, vol. 170, no. 8, 2023.
[5]
A. Abbadessa et al.,
"Layer-by-layer assembly of sustainable lignin-based coatings for food packaging applications,"
Progress in organic coatings, vol. 182, 2023.
[6]
J. White et al.,
"Electrodeposited PdNi on a Ni rotating disk electrode highly active for glycerol electrooxidation in alkaline conditions,"
Electrochimica Acta, vol. 403, 2022.
[7]
Z. Qiu et al.,
"Green hydrogen production via electrochemical conversion of components from alkaline carbohydrate degradation,"
International journal of hydrogen energy, vol. 47, no. 6, pp. 3644-3654, 2022.
[8]
W. Siwale et al.,
"Influence on off-gassing during storage of Scots pine wood pellets produced from sawdust with different extractive contents,"
Biomass and Bioenergy, vol. 156, 2022.
[9]
R. Deshpande et al.,
"Structural basis for lignin recalcitrance during sulfite pulping for production of dissolving pulp from pine heartwood,"
Industrial crops and products (Print), vol. 177, 2022.
[10]
W. Siwale et al.,
"Understanding Off-Gassing of Biofuel Wood Pellets Using Pellets Produced from Pure Microcrystalline Cellulose with Different Additive Oils,"
Energies, vol. 15, no. 6, pp. 2281, 2022.
[11]
E. Heinonen et al.,
"Xylan adsorption on cellulose : Preferred alignment and local surface immobilizing effect,"
Carbohydrate Polymers, vol. 285, pp. 119221-119221, 2022.
[12]
A. Anukam et al.,
"A review of the mechanism of bonding in densified biomass pellets,"
Renewable & sustainable energy reviews, vol. 148, 2021.
[13]
S. Frodeson et al.,
"Densification of Wood-Influence on Mechanical and Chemical Properties when 11 Naturally Occurring Substances in Wood Are Mixed with Beech and Pine,"
Energies, vol. 14, no. 18, 2021.
[14]
D. Martin-Yerga, G. Henriksson and A. M. Cornell,
"Insights on the ethanol oxidation reaction at electrodeposited PdNi catalysts under conditions of increased mass transport,"
International journal of hydrogen energy, vol. 46, no. 2, pp. 1615-1626, 2021.
[15]
D. Martín-Yerga et al.,
"Structure–Reactivity Effects of Biomass-based Hydroxyacids for Sustainable Electrochemical Hydrogen Production,"
ChemSusChem, vol. 14, no. 8, pp. 1902-1912, 2021.
[16]
J. Berglund et al.,
"Acetylation and Sugar Composition Influence the (In)Solubility of Plant beta-Mannans and Their Interaction with Cellulose Surfaces,"
ACS Sustainable Chemistry and Engineering, vol. 8, no. 27, pp. 10027-10040, 2020.
[17]
R. Deshpande et al.,
"Lignin carbohydrate complex studies during kraft pulping for producing paper grade pulp from birch,"
TAPPI Journal, vol. 19, no. 9, pp. 447-460, 2020.
[18]
P. A. Lindén et al.,
"Stabilising mannose using sodium dithionite at alkaline conditions,"
Holzforschung, vol. 74, no. 2, pp. 131-140, 2020.
[19]
J. Berglund et al.,
"Wood hemicelluloses exert distinct biomechanical contributions to cellulose fibrillar networks,"
Nature Communications, vol. 11, no. 1, 2020.
[20]
I. Dogaris, M. Lindström and G. Henriksson,
"Critical parameters for tall oil separation I : The importance of the ratio of fatty acids to rosin acids,"
TAPPI Journal, vol. 18, no. 9, pp. 547-555, 2019.
[21]
D. Martín-Yerga, G. Henriksson and A. M. Cornell,
"Effects of Incorporated Iron or Cobalt on the Ethanol Oxidation Activity of Nickel (Oxy)Hydroxides in Alkaline Media,"
Electrocatalysis, 2019.
[22]
J. Berglund et al.,
"Hydrogels of bacterial cellulose and wood hemicelluloses as a model of plant secondary cell walls,"
Abstracts of Papers of the American Chemical Society, vol. 257, 2019.
[23]
C. Moser, G. Henriksson and M. Lindström,
"Structural aspects on the manufacturing of cellulose nanofibers from wood pulp fibers,"
BioResources, vol. 14, no. 1, pp. 2269-2276, 2019.
[24]
I. Dogaris, M. Lindström and G. Henriksson,
"Study on tall oil solubility for improved resource recovery in chemical pulping of wood,"
Abstracts of Papers of the American Chemical Society, vol. 257, 2019.
[25]
I. Dogaris, M. Lindström and G. Henriksson,
"Tall Oil Solubility in Industrial Liquors,"
Stokcholm, Energiforsk, 2019:282, 2019.
[26]
A. Abbadessa, P. Oinonen and G. Henriksson,
"Characterization of Two Novel Bio-based Materials from Pulping Process Side Streams : Ecohelix and CleanFlow Black Lignin,"
BioResources, vol. 13, no. 4, pp. 7606-7627, 2018.
[27]
C. Moser, G. Henriksson and M. Lindström,
"Improved dispersibility of once-dried cellulose nanofibers in the presence of glycerol,"
Nordic Pulp & Paper Research Journal, vol. 33, no. 4, pp. 647-650, 2018.
[28]
A. Martinez-Abad et al.,
"Influence of the molecular structure of wood hemicelluloses on the recalcitrance of lignocellulosic biomass,"
Abstracts of Papers of the American Chemical Society, vol. 255, 2018.
[29]
G. Henriksson et al.,
"Non-cellulose wood polysaccharides - a need for a stricter structural and functional classification?,"
Abstracts of Papers of the American Chemical Society, vol. 255, 2018.
[30]
R. Deshpande et al.,
"The reactivity of lignin carbohydrate complex (LCC) during manufacture of dissolving sulfite pulp from softwood,"
Industrial crops and products (Print), vol. 115, pp. 315-322, 2018.
[31]
J. Berglund et al.,
"The structure of galactoglucomannan impacts the degradation under alkaline conditions,"
Cellulose, 2018.
[32]
Y. Zhao, C. Moser and G. Henriksson,
"Transparent Composites Made from Tunicate Cellulose Membranes and Environmentally Friendly Polyester,"
ChemSusChem, vol. 11, no. 10, pp. 1728-1735, 2018.
[33]
C. Moser et al.,
"Xyloglucan adsorption for measuring the specific surface area on various never-dried cellulose nanofibers,"
Nordic Pulp & Paper Research Journal, vol. 33, no. 2, pp. 186-193, 2018.
[34]
C. Moser et al.,
"Xyloglucan for estimating the surface area of cellulose fibers,"
Nordic Pulp & Paper Research Journal, vol. 33, no. 2, pp. 194-199, 2018.
[35]
S. Aminzadeh, L. Zhang and G. Henriksson,
"A possible explanation for the structural inhomogeneity of lignin in LCC networks,"
Wood Science and Technology, vol. 51, no. 6, pp. 1365-1376, 2017.
[36]
X. Geng et al.,
"Bioinspired Ultrastable Lignin Cathode via Graphene Reconfiguration for Energy Storage,"
ACS Sustainable Chemistry and Engineering, vol. 5, no. 4, pp. 3553-3561, 2017.
[37]
Y. Zhao et al.,
"Cellulose Nanofibers from Softwood, Hardwood, and Tunicate : Preparation-Structure-Film Performance Interrelation,"
ACS Applied Materials and Interfaces, vol. 9, no. 15, pp. 13508-13519, 2017.
[38]
Y. Zhao et al.,
"Film formation and performance of different nanocelluloses obtained from different cellulose sources after different preparation processes,"
Abstracts of Papers of the American Chemical Society, vol. 253, 2017.
[39]
N. Giummarella et al.,
"On the effect of hemicellulose removal on celluloselignin interactions,"
Nordic Pulp & Paper Research Journal, vol. 32, no. 4, pp. 542-549, 2017.
[40]
N. Giummarella et al.,
"On the effect of hemicellulose removal on cellulose-lignin interactions,"
Nordic Pulp & Paper Research Journal, vol. 32, no. 4, pp. 542-549, 2017.
[41]
A. Martinez-Abad et al.,
"Regular Motifs in Xylan Modulate Molecular Flexibility and Interactions with Cellulose Surfaces,"
Plant Physiology, vol. 175, no. 4, pp. 1579-1592, 2017.
[42]
T. Mattsson et al.,
"The Development of a Wood-based Materials-biorefinery,"
BioResources, vol. 12, no. 4, pp. 9152-9182, 2017.
[43]
R. Bi et al.,
"A Method for Studying Effects on Lignin-Polysaccharide Networks during Biological Degradation and Technical Processes of Wood,"
BioResources, vol. 11, no. 1, pp. 1307-1318, 2016.
[44]
J. Berglund et al.,
"A molecular dynamics study of the effect of glycosidic linkage type in the hemicellulose backbone on the molecular chain flexibility,"
The Plant Journal, 2016.
[45]
P. Oinonen et al.,
"Bioinspired composites from cross-linked galactoglucomannan and microfibrillated cellulose : Thermal, mechanical and oxygen barrier properties,"
Carbohydrate Polymers, vol. 136, pp. 146-153, 2016.
[46]
N. Giummarella et al.,
"Global protocol for the mild quantitative fractionation of lignin carbohydrate complexes (LCC),"
Abstracts of Papers of the American Chemical Society, vol. 251, 2016.
[47]
J. Berglund et al.,
"How the flexibility properties of hemicelluloses are affected by the glycosidic bonds between different backbone sugars - A molecular dynamics study,"
Abstracts of Papers of the American Chemical Society, vol. 251, 2016.
[48]
R. Bi, S. Huang and G. Henriksson,
"ISOLATION OF EXCEEDINGLY LOW OXYGEN CONSUMING FUNGAL STRAINS ABLE TO UTILIZE LIGNIN AS CARBON SOURCE,"
Cellulose Chemistry and Technology, vol. 50, no. 7-8, pp. 811-817, 2016.
[49]
N. Giummarella et al.,
"Lignin Prepared by Ultrafiltration of Black Liquor : Investigation of Solubility, Viscosity, and Ash Content,"
BioResources, vol. 11, no. 2, pp. 3494-3510, 2016.
[50]
S. Aminzadeh et al.,
"On the crossflow membrane fractionation of lignoboost kraft lignin : Characterization of low molecular weight fractions,"
Abstracts of Papers of the American Chemical Society, vol. 251, 2016.