Molecular Oxygen Lignin Depolymerization: An Insight into the Stability of Phenolic Monomers

Mathieu, Yannick; Vidal, Juan D.; Ochoa-Martínez, Luz Araceli; Fernández, Nerea Abad; Iborra, Sara; Corma, Avelino

doi:10.1002/cssc.202001295

Cited by 16 publications

(7 citation statements)

References 69 publications

(153 reference statements)

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“…48,49 We believed that an appropriate reaction temperature is essential for the oxidative depolymerization process to maintain the balance between the reactivity of the native lignocellulose substrate and the stability of protocatechuic aldehyde and protocatechuic acid products. 47,50 These thermal stability results helped us get insights into the characteristics of the C-type aromatic products despite their unsatisfactory yields, which also demonstrate the possibility of C-lignin valorization by the oxidation strategy under moderate conditions.…”

Section: Resultsmentioning

confidence: 87%

Catalytic oxidative conversion of C/G-type lignin coexisting in Tung nutshells to aromatic aldehydes and acids

Xie,

Zhu,

et al. 2023

New J. Chem.

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Section: Resultsmentioning

confidence: 87%

Catalytic oxidative conversion of C/G-type lignin coexisting in Tung nutshells to aromatic aldehydes and acids

Xie,

Zhu,

et al. 2023

New J. Chem.

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“…To investigate this aspect, the oxidized organosolv lignin 22 was submitted to column chromatography. While the significant difficulties encountered with solubilization point to the fact that the oxidized lignin 22 has remained largely polymeric, two aldehydes, vanillin ( 23a ) and syringaldehyde ( 23b ), could be separated and identified. ,,,,, The oxidation step can thus be described as shown in Scheme , where the yields of 23a and 23b were calculated on the basis of the estimated average mass of 200 g/mol per lignin monomer (see above). As an example, the yields from an oxidation experiment with 1 g of organosolv lignin 21 refer to 5 mmol of starting material.…”

Section: Resultsmentioning

confidence: 99%

“…Regarding plausible pathways leading to the formation of phenols 17a – d from organosolv lignin (Scheme ), the intermediates vanillin ( 23a ) and syringaldehyde ( 23b ) are well known as possible cleavage products resulting from lignin under oxidative conditions (Figure ). ,,,,, …”

Section: Resultsmentioning

confidence: 99%

“…Regarding plausible pathways leading to the formation of phenols 17a−d from organosolv lignin (Scheme 5), the intermediates vanillin (23a) and syringaldehyde (23b) are well known as possible cleavage products resulting from lignin under oxidative conditions (Figure 1). 7a,b,9a,b,12b, 26 Control experiments revealed that 23a and 23b are even present in small amounts in the organosolv lignin 21 used as starting material (23a: 1.11%, 23b: 0.53%), but when treated separately under the oxidative conditions comprising nitrogen monoxide and DDQ, they turned out to be unstable, and full decomposition to a complex product mixture was observed. Accordingly, the aldehydes 23a and 23b are formed as well as partially decomposed in the oxidation step, leading from 21 to oxidized lignin 22, which is a plausible background for deviations in yields even in identical experiments.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

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Cleavage of Organosolv Lignin to Phenols Using Nitrogen Monoxide and Hydrazine

et al. 2021

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From the variety of methods known for the depolymerization of organosolv lignin, a broad range of diversely substituted aromatic compounds are available today. In the present work, a novel two-step reaction sequence is reported, which is focused on the formation of phenols. While the first step of the depolymerization strategy comprises the 2,3-dichloro-5,6-dicyano-1,4-benzoquinone (DDQ)-catalyzed oxidation of organosolv lignin with nitrogen monoxide so that two waste materials are combined, cleavage to the phenolic target compounds is achieved in the second step employing hydrazine and potassium hydroxide under Wolff–Kishner-type conditions. Besides the fact that the novel strategy proceeds via an untypical form of oxidized organosolv lignin, the two-step sequence is further able to provide phenols as cleavage products, which bear no substituent at the 4-position.

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“…The stability of certain phenolic derivatives, produced by this route, has been studied to propose the corresponding oxidation mechanism. 26 For this purpose, the redox potential of the catalyst should be low but high enough to oxidize the phenolate anion. Thus, species such as Cu salts, which have a moderate redox potential, are good candidates for the biobased vanillin production from lignin.…”

Section: Introductionmentioning

confidence: 99%

Biobased Vanillin Production by Oxidative Depolymerization of Kraft Lignin on a Nitrogen- and Phosphorus-Functionalized Activated Carbon Catalyst

García-Rollán,

Rivas-Márquez,

Bertran-Llorens

et al. 2024

Energy Fuels

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The sustainable production of vanillin from the oxidative depolymerization of lignin was evaluated. Vanillin was produced from Kraft lignin using heterogeneous catalysts based on activated carbons prepared by chemical activation of sodium lignosulfonate with H 3 PO 4 . The novel redox catalytic system, obtained by HNO 3 treatment, allows the heterogenization of nitrobenzene structures on the activated carbon, reaching vanillin yield 30% higher than that obtained without a heterogeneous catalyst (about 3.1 wt %). A copper catalyst (5 wt %) was also prepared for comparison purposes. The highest vanillin yield was obtained at 200 °C and 10 bar for the nitrobenzene-like catalyst, reaching full extraction from the selected technical lignin. The catalyst was successfully reused without any regeneration treatment, evidencing no signs of deactivation. The possibility of transferring oxygen from oxidized P groups to reduced N groups in a redox cycle seems to be responsible for this sustained catalytic activity. To promote zero waste production, the obtained residual lignin was also used to prepare an activated carbon with outstanding properties, A BET ∼ 1000 m 2 /g.

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Molecular Oxygen Lignin Depolymerization: An Insight into the Stability of Phenolic Monomers

Cited by 16 publications

References 69 publications

Catalytic oxidative conversion of C/G-type lignin coexisting in Tung nutshells to aromatic aldehydes and acids

Catalytic oxidative conversion of C/G-type lignin coexisting in Tung nutshells to aromatic aldehydes and acids

Cleavage of Organosolv Lignin to Phenols Using Nitrogen Monoxide and Hydrazine

Biobased Vanillin Production by Oxidative Depolymerization of Kraft Lignin on a Nitrogen- and Phosphorus-Functionalized Activated Carbon Catalyst

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