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Papers
61,005 resultsShowing papers similar to A waterproof cellulose nanofibril sheet prepared by the deposition of an alkyl ketene dimer on a controlled porous structure
ClearPreparation and Characterization of Degradable Cellulose−Based Paper with Superhydrophobic, Antibacterial, and Barrier Properties for Food Packaging
Researchers prepared food packaging paper coated with polylactic acid and cinnamaldehyde as a barrier layer and nano silica-modified stearic acid as a superhydrophobic outer layer, creating a cellulose-based alternative to plastic packaging. The resulting material showed excellent water resistance, thermal stability, and antimicrobial activity while being made from renewable and biodegradable components.
Design of cellulose nanofibre-based composites with high barrier properties
Researchers tested four types of cellulose nanofibres and two clay mineral combinations for making composite films with gas barrier properties, finding that TEMPO-oxidized and cationized nanofibres with clay minerals produced films with superior mechanical and barrier performance. These plant-derived composites offer a sustainable alternative to petroleum-based packaging films.
Flexible Cellulose Nanofiber (CNF)-Nano- Montmorillonite (MMT) Composite Sheet Structure and Water Vapor Barrier Performance
Researchers developed flexible composite sheets by spray-coating nano-montmorillonite (MMT) into cellulose nanofiber (CNF) suspensions, finding that increasing MMT content significantly reduced water vapor permeability compared to CNF films alone, offering a biodegradable alternative to plastic packaging.
Cellulose nanofibers/polyvinyl alcohol blends as an efficient coating to improve the hydrophobic and oleophobic properties of paper
Researchers developed a paper coating made from cellulose nanofibers and polyvinyl alcohol and found it significantly improved paper's resistance to both water and grease while also increasing tensile strength, offering a potentially more sustainable alternative to the plastic-based coatings currently used in food packaging.
The Hydrophobicity of Lignocellulosic Fiber Network Can Be Enhanced with Suberin Fatty Acids
Researchers extracted suberin fatty acids from birch bark and used them to create hydrophobic fiber network sheets as a potential natural alternative to plastic-coated packaging materials. The resulting material repelled water while remaining breathable, offering a promising bio-based substitute that could reduce plastic use in food and material packaging.
Recent Advances in Superhydrophobic and Antibacterial Cellulose-Based Fibers and Fabrics: Bio-inspiration, Strategies, and Applications
Researchers review fabrication strategies for superhydrophobic and antibacterial cellulose fabrics, covering surface micro/nanostructure construction, chemical modification, and antimicrobial agent integration — and discuss how liquid-repellent surfaces reduce bacterial adhesion as a sustainable alternative to synthetic polymer textiles.
In Situ Synthesis of Plasticized Bacterial Cellulose Films for Daily Packaging Using Biobased Plasticizers
Researchers synthesized plasticized bacterial cellulose films in situ and characterized their mechanical, optical, and barrier properties for daily packaging applications, finding the bio-based materials offered competitive performance with lower environmental impact than petroleum-based alternatives.
Bio-Based Monoepoxy-TerminatedPolysiloxane-ModifiedCoating for Hydrophobic and Oil-Resistant Paper
Researchers developed a bio-based coating material by grafting monoepoxy-terminated polysiloxane onto chitosan and cellulose nanofibers via a one-pot method, producing films with tunable hydrophobic and oil-resistant properties for sustainable packaging paper as an alternative to nondegradable plastic coatings.
Effect of nanofibrillated cellulose on alginate and chitosan film properties as potential barrier coatings for paper food packaging
Researchers tested nanofibrillated cellulose as an additive for chitosan and alginate biopolymer films intended for food packaging applications. The study found that adding oxidized nanofibrillated cellulose improved the mechanical and barrier properties of the films, suggesting these biodegradable composites could serve as alternatives to conventional plastic packaging coatings.
A multifunctional biogenic films and coatings from synergistic aqueous dispersion of wood-derived suberin and cellulose nanofibers
Researchers developed multifunctional bio-based packaging films and coatings using suberin, an industrial byproduct, stabilized with amphiphilic cellulose nanofibers. The resulting materials demonstrated UV shielding and antimicrobial properties while serving as effective food packaging. The study presents a sustainable alternative to conventional plastic packaging that could help reduce microplastic pollution from packaging degradation.
Renewable cellulosic nanocomposites for food packaging to avoid fossil fuel plastic pollution: a review
Researchers reviewed how cellulose nanoparticles extracted from plant biomass can replace petroleum-based plastics in food packaging, finding that adding just 1–5% cellulose nanoparticles significantly improves strength, reduces oxygen and water vapor permeability, and keeps packaging biodegradable. The review positions cellulose nanocomposites as a scalable, eco-friendly alternative to fossil-fuel plastics that contribute to microplastic pollution.
Hydrophobic, Sustainable, High-Barrier Regenerated Cellulose Film via a Simple One-Step Silylation Reaction
Researchers developed hydrophobic, high-barrier regenerated cellulose films through a simple one-step gas-solid silylation reaction, creating a sustainable and biodegradable alternative to petroleum-based plastic packaging films.
Cellulose Nanopaper: A Study of Composition and Surface Modifications to Develop Sustainably-Sourced Alternatives to Plastics
This study developed cellulose nanopaper — derived from wood pulp — with surface modifications to improve its properties as a sustainable alternative to petroleum-based plastic packaging films. The research addresses the need for biodegradable packaging materials that reduce the plastic waste that becomes microplastic contamination.
Controlled surface acetylation of cellulosics to tune biodegradability while expanding their use towards common petrochemical-based plastics
Not relevant to microplastics — this study demonstrates surface acetylation of cellulose paper fibers to improve wet strength and moisture resistance while maintaining biodegradability, positioned as an alternative to petrochemical plastics.
Nanocellulose Coating on Kraft Paper
This paper is not directly about microplastics — it evaluates nanofibrillated cellulose coatings on kraft paper as a biodegradable alternative to plastic-based food packaging coatings, finding improvements in barrier properties, density, and mechanical strength.
Fabrication of water/oil-resistant paper by nanocellulose stabilized Pickering emulsion and chitosan
Researchers developed a plastic-free, biodegradable water- and oil-resistant paper coating using cellulose nanofibrils and chitosan in a Pickering emulsion system. The coating provided excellent barrier properties against water and oil while maintaining paper recyclability and compostability. The study offers a promising alternative to conventional plastic-based food packaging coatings that contribute to microplastic pollution.
New alternatives to single‐use plastics: Starch and chitosan‐graft‐polydimethylsiloxane‐coated paper for water‐ and oil‐resistant applications
Researchers developed a fluorine-free, bio-based paper coating using starch and chitosan grafted with polydimethylsiloxane, achieving water- and oil-resistance comparable to conventional fluorochemical coatings while remaining biodegradable and compostable.
Material properties and water resistance of inorganic–organic polymer coated cellulose paper and nanopaper
Researchers developed and characterised ORMOCER-coated cellulose paper and nanopaper as biodegradable, plastic-free alternatives for agricultural and packaging applications, finding that the inorganic-organic polymer coatings significantly improved water resistance while retaining the renewable and lightweight properties of the cellulose substrates.
The Quest Towards Superhydrophobic Cellulose and Bacterial Cellulose Membranes and Their Perspective Applications
This review examines advances in developing superhydrophobic cellulose and bacterial cellulose membranes, biopolymers that offer an eco-friendly alternative to synthetic polymers which generate microplastics and toxic substances. The review covers functionalization strategies that modify physical, chemical, and biological properties of these high-surface-area materials and surveys their emerging applications in filtration, oil-water separation, and environmental remediation.
Water repellency of cotton knitted fabrics treated with alkyl ketene dimers
Cotton knitted fabrics soaked in alkyl ketene dimer (AKD) dispersions acquired strong water repellency after curing at 120°C, with SEM revealing flake-like AKD structures on the fibers; the study offers a practical approach to making hydrophilic cotton fabrics water-repellent without fluorinated chemicals.
Advances in Cellulose-Based Packaging Films for Food Products
This review covers recent advances in cellulose-based packaging films as sustainable alternatives to petroleum-based plastics, examining how different cellulose structures and derivatives enable versatile film properties for food packaging applications.
Free standing nanocellulose films – fabrication methods, surface engineering and recyclability
This review examines fabrication methods, surface engineering approaches, and recyclability of free-standing nanocellulose films, highlighting their potential as sustainable alternatives to synthetic plastic films across various applications.
Recent Advances in Chemically Modified Cellulose and Its Derivatives for Food Packaging Applications: A Review
This review examined recent advances in chemically modified cellulose and its derivatives for food packaging applications, highlighting how cellulose-based biodegradable materials can replace petroleum-based plastics while discussing challenges in moisture barrier and mechanical properties.
Biodegradable Poly(butylene succinate) Laminate with Nanocellulose Interphase Layer for High-Barrier Packaging Film Application
Researchers developed a biodegradable food packaging film by layering nanofibrillated cellulose derived from hemp waste between blown poly(butylene succinate) films. The study found that even a single cellulose layer, making up just 0.35% of the composite's weight, reduced water vapor transmission by up to 5.5 times. This approach suggests a pathway toward sustainable packaging alternatives that reduce reliance on petroleum-based plastics.