Lignin Depolymerization into Aromatic Monomers over Solid Acid Catalysts

Deepa, Ayillath K.; Dhepe, Paresh L.

doi:10.1021/cs501371q

Cited by 290 publications

(212 citation statements)

References 81 publications

(230 reference statements)

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“…In Deepa's report (Deepa and Dhepe, 2015), lignin conversion generated wide range of products from 10 to 25 min. However, in this work, only seven products were detected by GC-MS, indicating much higher selectivity of this catalyst.…”

Section: Resultsmentioning

confidence: 99%

“…Among various catalysts for lignin depolymerization, zeolites are widely accepted due to their low-cost, high surface area, and outstanding acid sites catalytic performance (Taarning et al, 2011;Ben and Ragauskas, 2012;Wang et al, 2017). External Brønsted acidity in meso-/microporous zeolites was reported to effectively affect the selectivity of de-alkylation and de-etherification reactions in parallel during lignin conversion (Taarning et al, 2011;Singh and Ekhe, 2014;Deepa and Dhepe, 2015). Deepa reported that aromatic monomers were the predominant products using zeolite as solid acid catalysts for lignin depolymerization at 250°C in H2O/CH3OH mixture (Deepa and Dhepe, 2015).…”

Section: Introductionmentioning

confidence: 99%

“…External Brønsted acidity in meso-/microporous zeolites was reported to effectively affect the selectivity of de-alkylation and de-etherification reactions in parallel during lignin conversion (Taarning et al, 2011;Singh and Ekhe, 2014;Deepa and Dhepe, 2015). Deepa reported that aromatic monomers were the predominant products using zeolite as solid acid catalysts for lignin depolymerization at 250°C in H2O/CH3OH mixture (Deepa and Dhepe, 2015).…”

Section: Introductionmentioning

confidence: 99%

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High Catalytic Efficiency of Lignin Depolymerization over Low Pd-Zeolite Y Loading at Mild Temperature

et al. 2018

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GRAPHICAL ABSTRACT | High catalytic efficiency of lignin depolymerization over low Pd-zeolite Y loading at mild temperature. This article reported a novel low-temperature process for aromatics production through lignin depolymerization catalyzed by 0.1 wt% Pd-zeolite Y catalyst prepared by a facile method. Under the same reactive condition, the as-prepared Pd-zeolite Y catalysts exhibited much higher catalytic efficiency than zeolite Y or commercial Pd/Al2O3-zeolite composites. The selectivity of the Pd-zeolite Y toward lignin depolymerization was also much higher than the other commercial zeolite-based catalysts. With the presence of hydrogen, aromatics were the predominant products with high yields of phenols and dimers (over 99%). The as-obtained aromatics can be promising feedstock for production of fuels or chemicals for various applications. Results revealed that the Pd-zeolite Y catalyst is a highly active catalyst for the cleavage of lignin interlinkages, especially the C-O-C bonds by hydrogenolysis.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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High Catalytic Efficiency of Lignin Depolymerization over Low Pd-Zeolite Y Loading at Mild Temperature

et al. 2018

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“…4 As a natural amorphous three-dimensional polymer consisting mainly of methoxylated phenylpropane units, 2,5 lignin is linked to other main components, such as cellulose and hemicellulose, in a variety of ways, including hydrogen, ester, and covalent bonds. 6 Depolymerization of lignin is the key step towards making lignin cost-effective as a raw material, 7 but its highly random and branched three-dimensional polyphenolic structure leads to its resistance to depolymerization.…”

Section: Introductionmentioning

confidence: 99%

Catalytic alcoholysis of alkaline extracted lignin for the production of aromatic esters over SO₄²⁻/ZrO₂-ATP

Zhang

Pan

et al. 2018

RSC Adv.

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An efficient process for the depolymerization of alkaline extracted lignin (AEL) using attapulgite (ATP)-supported solid catalysts in ethanol was developed in this work. Different ATP-supported catalysts were prepared and used to catalyze the depolymerization of the lignin AEL. The results demonstrated that the addition of ATP-supported catalysts was favorable for controlling the distribution of valuable depolymerization products. The optimal solid catalyst SO 4 2À /ZrO 2 -ATP (Cat 2) exhibited high catalytic activity and selectivity, which showed a 78.6% conversion of AEL and a 29.4% selectivity to ethyl ferulate (ethyl 4-hydroxy-3-methoxycinnamate) with a catalyst/AEL ratio of 1 : 1 at 200 C for 120 min. The catalyst could be reused and its catalytic activity did not obviously decreased after 6 successive runs.Particularly, a plausible mechanism involving esterification, hydrogenation, and dehydration for the production of aromatic esters from AEL depolymerization over SO 4 2À/ZrO 2 -ATP in ethanol was also proposed.

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“…The rest of the available lignin is usually burned for providing the heat (Chapple et al, 2007) that does not satisfy the need for effective power generation. Different ways of lignin recycling by using catalysts and ionic liquids are reflected in numerous publications (Deepa & Dhepe, 2015., Nanayakkara et al, 2014 however these approaches are often expensive and do not meet the requirements for sustainable lignin recycling. One of the environmentally friendly approaches is to use naturally existing enzymes that are capable of degrading lignin and biomass (Christopher et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Mechanism of Alkaline Lignin Oxidation Using Laccase-methyl Syringate Mediator System

Yao¹,

Kolla²,

Koodali³

et al. 2016

IJC

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The mechanism of alkaline lignin oxidation in presence of laccase-methyl syringate (MS) mediator is discussed in terms of morphological changes that take place during exposure of the lignin to the phosphate buffer solution (pH=6.5) for 72hr at 70 o C. The SEM analysis of lignin before and after enzymatic treatment reveals the morphological changes explained by the interaction of the lignin surface groups with laccase-methyl syringate system. The BET analysis confirms that this interaction causes the change in the surface area from 2.75 to 5.50cm 2 /g. The corresponding pore-size distribution in lignin sample treated with laccase-methyl syringate is much broader in comparison to the untreated lignin and the pores within 25-150nm range are detected as a result of the BJH analysis. The electrochemical study of lignin, lignin with laccase, and lignin with laccase in presence of the mediator in the buffer solution has been performed in the potential range from -0.3 to +1.0V vs. Ag, AgCl, Cl -reference electrode. The cyclic voltammetry confirms reversible oxidation-reduction behavior of the methyl syringate natural mediator in anaerobic and aerobic environment. Specifically in anaerobic conditions three oxidation anodic peaks (0.265V, 0.474V and 0.884V) and two reduction peaks (0.421V and 0.103V) were detected out of which the oxidation peak at 0.474V was assigned to the formation of MS• radical. In aerobic conditions the methyl syringate demonstrates two oxidation peaks (0.473V and 0.812V) and two reduction peaks (0.410V and 0.135V). The mechanism of MS radical stability in oxygen vs. anaerobic environment is proposed based on formation of MS• radicals.

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Lignin Depolymerization into Aromatic Monomers over Solid Acid Catalysts

Cited by 290 publications

References 81 publications

High Catalytic Efficiency of Lignin Depolymerization over Low Pd-Zeolite Y Loading at Mild Temperature

High Catalytic Efficiency of Lignin Depolymerization over Low Pd-Zeolite Y Loading at Mild Temperature

Catalytic alcoholysis of alkaline extracted lignin for the production of aromatic esters over SO₄²⁻/ZrO₂-ATP

Mechanism of Alkaline Lignin Oxidation Using Laccase-methyl Syringate Mediator System

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Lignin Depolymerization into Aromatic Monomers over Solid Acid Catalysts

Cited by 290 publications

References 81 publications

High Catalytic Efficiency of Lignin Depolymerization over Low Pd-Zeolite Y Loading at Mild Temperature

High Catalytic Efficiency of Lignin Depolymerization over Low Pd-Zeolite Y Loading at Mild Temperature

Catalytic alcoholysis of alkaline extracted lignin for the production of aromatic esters over SO42−/ZrO2-ATP

Mechanism of Alkaline Lignin Oxidation Using Laccase-methyl Syringate Mediator System

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Catalytic alcoholysis of alkaline extracted lignin for the production of aromatic esters over SO₄²⁻/ZrO₂-ATP