Grafting strategies for hydroxy groups of lignin for producing materials

Kazzaz, Armin Eraghi; Feizi, Zahra Hosseinpour; Fatehi, Pedram

doi:10.1039/c9gc02598g

Cited by 152 publications

(72 citation statements)

References 241 publications

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“…In past decades, billions of tons of non-biodegradable plastics have been produced, which is a significant source of pollution. As an abundant natural polymer, lignin could be integrated into plastics to fabricate high-value biodegradable materials with economic competitiveness (Sen et al, 2015;Kazzaz et al, 2019). Therefore, the preparation of composite materials by mixing lignin with various plastics had attracted attention.…”

Section: Lignin-plastic Compositesmentioning

confidence: 99%

Multifunctional Lignin-Based Composite Materials for Emerging Applications

Kim

Liu

et al. 2021

Front. Bioeng. Biotechnol.

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Lignin exhibited numerous advantages such as plentiful functional groups, good biocompatibility, low toxicity, and high carbon content, which can be transformed into composites and carbon materials. Lignin-based materials are usually environmentally friendly and low cost, and are widely used in energy storage, environment, electronic devices, and other fields. In this review article, the pretreatment separation methods like hydrothermal process are illustrated briefly, and the properties and categories of technical lignin are introduced. Then, the latest progress of lignin-based composites and lignin-derived carbon materials is summarized. Finally, the current challenges and future developments were suggested based on our knowledge. It is expected that this review paper favored the applications of composites and lignin-derived carbon materials in the future.

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Section: Lignin-plastic Compositesmentioning

confidence: 99%

Multifunctional Lignin-Based Composite Materials for Emerging Applications

Kim

Liu

et al. 2021

Front. Bioeng. Biotechnol.

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“…For methylolation, the reaction conditions are comparable (alkaline medium and temperature range of 25−90°C) to glyoxalation; however, shorter reaction times are typically applied due to the higher reactivity of formaldehyde compared to glyoxal. 110 From Table 1, it can be concluded that most of the studies applied a glyoxal solution to lignin (G/L), mass ratio between 0.1 and 1 (glyoxal is typically supplied as a 40 wt % solution). However, it is difficult to compare all glyoxal:lignin ratios applied in the different studies.…”

Section: ■ Glyoxalation Of Ligninmentioning

confidence: 99%

Biobased Resins Using Lignin and Glyoxal

Nieuwenhove

Renders

Lauwaert

et al. 2020

ACS Sustainable Chem. Eng.

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The utilization of lignin and glyoxal as potentially sustainable and less hazardous building blocks for phenolic resins is an emerging research field. Lignin thereby serves as a partial, macromolecular substitute for phenol, while glyoxal fulfills the role of an aldehyde cross-linker. In the first part of this perspective, the industrial context of lignin and glyoxal will be expounded with a focus on their origin and production processes. In the framework of phenolic resins, the use of lignin and glyoxal can be categorized into two research domains: (i) glyoxalation to improve the reactivity of lignin prior to resin synthesis and (ii) direct resin synthesis using lignin and glyoxal with glyoxal immediately serving as the cross-linker. This perspective provides a comprehensive overview of the progress made in both domains, pinpointing the opportunities, blind spots, and challenges that lay ahead.

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“…Signals at δ 3.9 to 3.6 are assigned to -OCH3 hydrogens and ~ δ 3.3 to -CH2 hydrogens from hydroxymethyl groups (Jiao et al 2018). During sulfomethylation, formaldehyde introduces a hydroxymethyl group into the lignin at the C5 position of the aromatic ring, which is the main reaction location in the sulfonation reaction with sodium sulfite (Yu et al 2013;Kazzaz et al 2019). Thus, the increase in the signal intensity in this region is due to the introduction of hydroxymethyl groups in the OSKL.…”

Section: H Nuclear Magnetic Resonance (Nmr) Spectroscopymentioning

confidence: 99%

“…The sulfomethylation reaction of lignin involves the addition of a methylene sulfonate group (-CH2SO3) into the aromatic ring, i.e., the C5 position of G-type lignin. Briefly, the precursors formaldehyde (CH2O) and sodium sulfite (Na2SO3) under determined reaction parameters combine to form sodium hydroxymethyl sulfonate, the reactive species responsible for introducing the sulfonic group into lignin (Meister 2002;Konduri and Fatehi 2015;Huang et al 2018;Kazzaz et al 2019). However, due to the complex and highly branched polyphenolic structure of lignin along with the sulfomethylation reaction conditions, different degrees of sulfonation and structural changes of lignin can be promoted, which could affect the depression performance of the lignin-derived product.…”

Section: Introductionmentioning

confidence: 99%

Sulfomethylation of radiata pine kraft lignin and its use as a molybdenite depressant in selective chalcopyrite-molybdenite separation by flotation

Vidal

Carrillo-Varela

Reyes-Contreras³

et al. 2021

BioRes

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Sulfomethylation of radiata pine kraft lignin was performed using formaldehyde and sodium sulfite under alkaline conditions to determine its potential as a mineral depressant for the separation of molybdenite and chalcopyrite by froth flotation. Optimal conditions for the sulfomethylation reaction were 20% (w/w) Na2SO3 at 130 °C for 4.2 h, which resulted in lignin with a sulfonate content of 2.2 mmol/g. Microflotation assays showed that the optimized sulfomethylated kraft lignin (OSKL) depressed the molybdenite in flotation by 93% using 200 mg/L OSKL, while only 5% chalcopyrite depression was achieved. The performance of OSKL was compared with those of commercial lignosulfonates, and the OSKL displayed a better ability to separate molybdenite and chalcopyrite, even at lower concentration doses. FTIR and 1H-NMR analyses showed that sulfonic groups were incorporated into the C5 position of the aromatic ring and into the aliphatic chain of the OSKL. The hydroxymethyl content of the OSKL was increased, and most β-O-4′, β-1′ and β-5′ bonds were broken, with the exception of the β-β’ bond. Sulfomethylation gives kraft lignin the chemical characteristics of a wood-based molybdenite depressant, making it an alternative to current reagents used in the chalcopyrite-molybdenite flotation process.

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Grafting strategies for hydroxy groups of lignin for producing materials

Cited by 152 publications

References 241 publications

Multifunctional Lignin-Based Composite Materials for Emerging Applications

Multifunctional Lignin-Based Composite Materials for Emerging Applications

Biobased Resins Using Lignin and Glyoxal

Sulfomethylation of radiata pine kraft lignin and its use as a molybdenite depressant in selective chalcopyrite-molybdenite separation by flotation

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