Sustainable Surface Engineering of Lignocellulose and Cellulose by Synergistic Combination of Metal‐Free Catalysis and Polyelectrolyte Complexes

A sustainable strategy for synergistic surface engineering of lignocellulose and cellulose fibers derived from wood by synergistic combination of metal‐free catalysis and renewable polyelectrolyte (PE) complexes is disclosed. The strategy allows for improvement and introduction of important properti...

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Bibliographic Details
Published in:Global challenges 2019-07, Vol.3 (7), p.1900018-n/a
Main Authors: Alimohammadzadeh, Rana, Osong, Sinke H., Rafi, Abdolrahim A., Dahlström, Christina, Cordova, Armando
Format: Article
Language:English
Subjects:
Acids
Bleaching
Carboxymethylcellulose
Catalysis
Catalysts
Cellulose
Cellulose fibers
Chemical synthesis
click chemistry
Communication
Communications
Confocal microscopy
Engineering
Fibers
Fluorescence
Hydrophobicity
Lignin
Lignocellulose
Metals
metal‐free catalysis
Microscopy
Organic acids
Organic chemistry
Polyelectrolytes
Polysaccharides
Pulp
Saccharides
selective fluorescent labeling
Sheets
Starch
Strength
Sustainable materials
sustainable polyelectrolyte complex
synergistic surface engineering
water repellent
Water resistance
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Summary:A sustainable strategy for synergistic surface engineering of lignocellulose and cellulose fibers derived from wood by synergistic combination of metal‐free catalysis and renewable polyelectrolyte (PE) complexes is disclosed. The strategy allows for improvement and introduction of important properties such as strength, water resistance, and fluorescence to the renewable fibers and cellulosic materials. For example, the “green” surface engineering significantly increases the strength properties (up to 100% in Z‐strength) of chemi‐thermomechanical pulp (CTMP) and bleached sulphite pulp (BSP)‐derived sheets. Next, performing an organocatalytic silylation with a nontoxic organic acid makes the corresponding lignocellulose and cellulose sheets hydrophobic. A selective color modification of polysaccharides is developed by combining metal‐free catalysis and thiol‐ene click chemistry. Next, fluorescent PE complexes based on cationic starch (CS) and carboxymethylcellulose (CMC) are prepared and used for modification of CTMP or BSP in the presence of a metal‐free catalyst. Laser‐scanning confocal microscopy reveals that the PE‐strength additive is evenly distributed on the CTMP and heterogeneously on the BSP. The fluorescent CS distribution on the CTMP follows the lignin distribution of the lignocellulosic fibers. A sustainable strategy for surface engineering of lignocellulose and cellulose fibers derived from wood by synergistic combination of metal‐free catalysis and renewable polyelectrolyte complexes is disclosed. The strategy allows for improvement and introduction of important properties such as strength, water resistance, and fluorescence to the renewable fibers and cellulosic materials.
ISSN:2056-6646
2056-6646
DOI:10.1002/gch2.201900018