Novel applications of lignin in composite materials

Thielemans, Wim; Can, Erde; Morye, S.S.; Wool, Richard P.

doi:10.1002/app.2247

Cited by 221 publications

(139 citation statements)

References 13 publications

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“…Finally, lignified materials effectively resist attacks by micro organisms by impeding penetration of destructive enzymes into the cell walls. When incorporated in a plastic, lignin, due to its phenolic base structure, could improve the mechanical properties (Thielemans et al, 2002). Fig.…”

Section: Ligninmentioning

confidence: 99%

Thermoplastic Matrix Reinforced with Natural Fibers: A Study on Interfacial Behavior

Farsi¹

2012

Some Critical Issues for Injection Molding

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Section: Ligninmentioning

confidence: 99%

Thermoplastic Matrix Reinforced with Natural Fibers: A Study on Interfacial Behavior

Farsi¹

2012

Some Critical Issues for Injection Molding

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“…Lignin has interesting grafting and cross-linking abilities that make it an interesting material for use in polyvinyl alcohol (PVOH) and other polymeric systems. Lignin has been proven to be degradable by certain wood-rotting fungi, such as white rot fungi, which makes it possible to break down lignin-based materials in some environments (Mousavioun et al 2012;Thielemans et al 2002;Yamamoto et al 2000).…”

Section: Introductionmentioning

confidence: 99%

Characterization of Cross-linked Alkaline Lignin/Poly (Vinyl Alcohol) Film with a Formaldehyde Cross-linker

Su¹,

Gui-zhen²

2014

BioResources

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On the basis of previous experiments, industrial alkaline lignin/poly (vinyl alcohol) (PVOH) cross-linked films, industrial alkaline lignin/poly (vinyl alcohol) blend films, and neat poly (vinyl alcohol) films were prepared by casting. The films were investigated by Fourier transform infra-red spectroscopy (FTIR), X-ray diffraction (XRD), thermogravimetry analysis (TGA), and dynamic mechanical analysis (DMA). The water contact angles for the three kinds of films were studied as well. The crosslinking reaction between alkaline lignin and PVOH was strong, which was attributed to the high hydrolysis degree of PVOH and the high reactivity of formaldehyde. Compared with the neat PVOH film, the crystallinity of the cross-linked film decreased slightly; the thermal stability of the crosslinked film was higher; DMA analysis showed that the Tg and the tanδ magnitude of the alkaline lignin/PVOH reaction film both decreased slightly. Lignin and the cross-linking reaction both improved the water resistance of films. Therefore, this research has provided a detailed analysis of the characterization of the films while exploring the potential of direct usage of industrial alkaline lignin in polymer materials.

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“…Completely ecofriendly Thielemans et al (2002) prepared a binderless board by heating and pressing cellulosic fibers at high temperature. Lignin, an amorphous component, starts plasticizing at a high temperature (above 200 °C) and behaves like a thermoplastic resin (Lora and Glasser 2002).…”

Section: Hydrophilicmentioning

confidence: 99%

Laccase, an Emerging Tool to Fabricate Green Composites: A Review

Mahmood¹,

Hashim²,

Sulaiman³

et al. 2015

BioResources

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In the last two decades, laccases have received much attention from researchers because of their specific ability to oxidize lignin. This function of laccase is very useful for applications in several biotechnological processes, including delignification in the pulp and paper industry and the detoxification of industrial effluents from the textile and petrochemical industries. This review focuses on laccase-mediated fiberboard synthesis. Growing concerns regarding the emission of formaldehyde from wood composites has prompted industrialists to consider the fabrication of green composites. Laccase-mediated fiber treatments oxidize the lignin component without affecting the cellulose structure. As a result, free radicals are generated on the fiber surface, and these can act as potential reactive sites for further cross-linking reactions in board manufacturing. Binderless fiberboards prepared using such methods can be considered as green composites because the manufacturing process involves no additional resin.

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Novel applications of lignin in composite materials

Cited by 221 publications

References 13 publications

Thermoplastic Matrix Reinforced with Natural Fibers: A Study on Interfacial Behavior

Thermoplastic Matrix Reinforced with Natural Fibers: A Study on Interfacial Behavior

Characterization of Cross-linked Alkaline Lignin/Poly (Vinyl Alcohol) Film with a Formaldehyde Cross-linker

Laccase, an Emerging Tool to Fabricate Green Composites: A Review

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