Nanocellulose Hybrid Lignin Complex Reinforces Cellulose to Form a Strong, Water-Stable Lignin–Cellulose Composite Usable as a Plastic Replacement

Bai, Feitian; Dong, Tengteng; Chen, Wei; Wang, Jinlong; Li, Xusheng

doi:10.3390/nano11123426

Cited by 10 publications

(3 citation statements)

References 57 publications

(58 reference statements)

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“…This shows that the addition of lignin can improve the wet strength of the film to a certain extent. There are three reasons: The hydroxyl group in lignin forms intermolecular hydrogen bond with the hydroxyl group of cellulose, which reduces the destruction of hydrogen bond of cellulose by water molecule; lignin contains some hydrophobic bonds, but also effective resistance to water molecules on the film damage; the hydrophobic lignin can fill the blank of the fiber network, and form a network between lignin to strengthen the fiber network, which limits the water absorption and expansion of the fiber, and improves the tensile strength of the film 36 . In the analysis of significant variance, we can also see that the addition of lignin to improve the tensile strength of the film is significant ( p < 0.05).…”

Section: Resultsmentioning

confidence: 99%

Beyond waste: Transforming wheat straw into oxygen and UV‐resistant cellulose films

Tang,

Han,

et al. 2024

J of Applied Polymer Sci

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Regenerated cellulose membrane is a biomaterial obtained by activating, dissolving, solidifying, and regenerating cellulose powder using solvents of different polarities. It has the characteristics of high oxygen resistance and high strength. However, its low water vapor barrier and single function limit its application. In order to improve the water resistance of regenerated cellulose membranes and endow them with UV resistance, lignin was extracted from waste wheat straw using formic acid method. The extracted formic acid lignin (FAL) was added to the cellulose solution to prepare a series of regenerated lignocellulosic membranes (RC‐FAL) with different lignin contents. The results indicate that lignin can not only improve the water vapor barrier, tensile strength, and water resistance of the film, but also enhance the oxygen barrier and UV absorption of the film. Compared with pure cellulose film, the contact angle of lignocellulose film can be increased by 66.2%, the UV absorption rate can reach 100%, and the oxygen transmission coefficient has no significant effect. In this paper, a new kind of biological packaging material with high oxygen resistance, strong ultraviolet absorption, and water resistance was prepared by recycling waste wheat straw, it has a broad application prospect in the industrial production of packaging materials.

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Section: Resultsmentioning

confidence: 99%

Beyond waste: Transforming wheat straw into oxygen and UV‐resistant cellulose films

Tang,

Han,

et al. 2024

J of Applied Polymer Sci

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“…Bai et al enzymatically hydrolyzed bagasse to produce lignin from bagasse residues. 112 They added different mass proportions of lignin to the bleached fiber pulp extracted from pine trees and then hot-pressed these pulps at 150 °C and 4 MPa for 30 min to produce lignin-cellulose flakes. The introduction of enzymatic lignin significantly improved the tensile strength and water stability of cellulose.…”

Section: Exogenous Ligninmentioning

confidence: 99%

Lignin-enhanced wet strength of cellulose-based materials: a sustainable approach

Huang

Zhu

et al. 2023

Green Chem.

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“…The excessive use of synthetic plastic products has accelerated the consumption of fossil energy and led to the worsening problem of white pollution. , First, the high cost of recycling greatly has increased the challenge of sustainable use of waste plastics. Second, the burning of waste plastic products has produced large numbers of greenhouse gases and harmful microplastics from the decomposition process, posing an unprecedented potential risk to global climate change as well as to ecosystems and human health. , Subsequently, it has become an urgent task to reduce the use of single-use plastics as much as possible where allowed while seeking sustainable and environmentally friendly alternatives to plastics. Natural wood, an abundant biomass resource, consists mainly of cellulose, hemicellulose, and lignin. , Wood-based composites have already been considered as strong candidates for sustainable applications to replace the widely used petrochemical plastics .…”

Section: Introductionmentioning

confidence: 99%

Composition Regulation of Free Delignification of Wood Powder toward High Performance, Recyclable Composites

Fang

Shi

Wang

et al. 2022

ACS Sustainable Chem. Eng.

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Wood-based structural materials have already shown great potential in engineering applications. However, the current research usually has been requiring partial removal of lignin and hemicellulose from wood, and the chemicals used in this process have been harmful to the environment and humans. In this study, a novel addition strategy without the delignification process was reported to design wood-based structural materials. Bacterial cellulose as a green binder and composition regulator was added into wood powder aqueous dispersion to form a wood powder− bacterial cellulose slurry. Superior mechanical properties, excellent water and thermal stability, and recyclability were achieved in this wood powder/bacterial cellulose composite. Furthermore, the composite exhibited pronounced flame retardancy due to the presence of inorganic salt components (calcium and magnesium carbonates). The wood modification strategy without delignification provides a new direction for the production of biodegradable and sustainable wood-based composites as a healthier alternative to petrochemical plastics.

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Nanocellulose Hybrid Lignin Complex Reinforces Cellulose to Form a Strong, Water-Stable Lignin–Cellulose Composite Usable as a Plastic Replacement

Cited by 10 publications

References 57 publications

Beyond waste: Transforming wheat straw into oxygen and UV‐resistant cellulose films

Beyond waste: Transforming wheat straw into oxygen and UV‐resistant cellulose films

Lignin-enhanced wet strength of cellulose-based materials: a sustainable approach

Composition Regulation of Free Delignification of Wood Powder toward High Performance, Recyclable Composites

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