One-pot lignin depolymerization and activation by solid acid catalytic phenolation for lightweight phenolic foam preparation

•Solid acid catalytic phenolation (SACP) is applied to treat enzymatic hydrolysis lignin (EHL).•EHL is depolymerized significantly during SACP treatment without condensation.•Phenol is incorporated into EHL by a nucleophilic reaction that stops lignin condensation.•Treated EHL shows increased phenol...

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Bibliographic Details
Published in:Industrial crops and products 2018-11, Vol.124, p.216-225
Main Authors: Wang, Guanhua, Liu, Xiaoqian, Zhang, Jiayin, Sui, Wenjie, Jang, Jinmyung, Si, Chuanling
Format: Article
Language:English
Subjects:
Enzymatic hydrolysis lignin
Lignin depolymerization
Lignin reactivity
Phenolic foam characterization
Solid acid catalytic phenolation
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Summary:•Solid acid catalytic phenolation (SACP) is applied to treat enzymatic hydrolysis lignin (EHL).•EHL is depolymerized significantly during SACP treatment without condensation.•Phenol is incorporated into EHL by a nucleophilic reaction that stops lignin condensation.•Treated EHL shows increased phenolic hydroxyl content and reactivity with formaldehyde.•50% phenol is substituted by treated EHL to prepare phenolic foam with satisfactory properties. Lignin valorization offers a significant opportunity for the commercial operation of a cellulosic ethanol-derived biorefinery. In this work, a novel solid acid catalytic phenolation (SACP) process was employed to treat enzymatic hydrolysis lignin (EHL) and the obtained product was further applied to prepare lightweight phenolic foams (ρ = 30–40 kg/m3). The changes of the molecular weight and structure of lignin under the SACP treatment were investigated by GPC, Py-GCMS, and 2D-NMR analyses. The results indicated that under the optimized SACP conditions (140 °C, 4% HZSM-5, and 2 h), the molecular weight (M¯w) of EHL sharply decreased from 6695 to 2418 g/mol without condensation. The Py-GCMS and 2D-NMR analyses suggested that phenol was incorporated at the Cα position through a nucleophilic reaction and this reaction inhibited the lignin condensation during the acidic treatment. Due to the simultaneous depolymerization and phenolation, the treated lignin showed noticeable increase in phenolic hydroxyl content and reactivity with formaldehyde. The further characterization of lignin-based phenolic foams showed that the treated lignin could replace 50% phenol to prepare phenolic foams with satisfactory thermal insulation and compression strength properties. Consequently, this work demonstrates that SACP is effective to depolymerize and activate lignin for high lignin content phenolic foam preparation and offers a value-added way of lignin application as heat-insulating foam materials.
ISSN:0926-6690
1872-633X
DOI:10.1016/j.indcrop.2018.07.080