Corrosion-resistant polyurethane coatings from structure-homogenized biorefinery lignin through fractionation and oxypropylation

Xiang Wang; R. M.Oshani Nayanathara; Weiqi Leng; Eugene B. Caldona; Liyang Liu; Rigoberto C. Advincula; Zhao Zhang; Xuefeng Zhang

doi:10.1016/j.jafr.2022.100452

Corrosion-resistant polyurethane coatings from structure-homogenized biorefinery lignin through fractionation and oxypropylation

Xiang Wang, R. M.Oshani Nayanathara, Weiqi Leng, Eugene B. Caldona, Liyang Liu, Rigoberto C. Advincula, Zhao Zhang, Xuefeng Zhang

Macromolecular Nanomaterials

Research output: Contribution to journal › Article › peer-review

30 Scopus citations

Abstract

Using lignin for polyurethane (PU) synthesis is challenging because of its heterogeneous structure, i.e., broad molecule weight (MW) distribution and diverse hydroxyl (OH) functionality. This complexity influences the crosslinking reaction between lignin and isocyanate and affects the quality of PU products. Here, we propose a two-step strategy for lignin structure homogenization by lowering its MW and uniforming OH functionality (step 2). Step 1 involves a bioethanol fractionation process, yielding fractionated lignin with one order lower MW than the raw lignin while exhibiting better processability for the subsequent process. Step 2 is performed by an oxyalkylation process using fractionated lignin that converts phenolic and carboxylic OHs to aliphatic OHs. As a result, we obtained structure-homogenized lignin with good compatibility and crosslinking with hexamethylene diisocyanate for PU coating synthesis. Moreover, PU coatings prepared from structure-homogenized lignin display a defect-free microscopic structure and show better corrosion resistance than coatings fabricated from its raw lignin alternative. Overall, the structure homogenization process is a beneficial way of using lignin as biopolyol in PU synthesis toward the application-oriented design of corrosion-resistant lignin-based PU coatings.

Original language	English
Article number	100452
Journal	Journal of Agriculture and Food Research
Volume	10
DOIs	https://doi.org/10.1016/j.jafr.2022.100452
State	Published - Dec 2022

Funding

The authors acknowledge the support of the National Natural Science Foundation of China , No. 51771173 . The authors thank Dr. S. Renneckar at the University of British Columbia for providing access to the NMR and GPC instruments for lignin characterization. Dr. X. Zhang acknowledges the support from Forest and Wildlife Research Center, Mississippi State University . Work (or part of this work) was conducted by ORNL's Center for Nanophase Materials Sciences by RCA, which is a US Department of Energy Office of Science User Facility. The authors acknowledge the support of the National Natural Science Foundation of China, No.51771173. The authors thank Dr. S. Renneckar at the University of British Columbia for providing access to the NMR and GPC instruments for lignin characterization. Dr. X. Zhang acknowledges the support from Forest and Wildlife Research Center, Mississippi State University. Work (or part of this work) was conducted by ORNL's Center for Nanophase Materials Sciences by RCA, which is a US Department of Energy Office of Science User Facility.

Keywords

Anticorrosive coating
Biorefinery lignin
Polyurethane
Structure homogenization

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title = "Corrosion-resistant polyurethane coatings from structure-homogenized biorefinery lignin through fractionation and oxypropylation",

abstract = "Using lignin for polyurethane (PU) synthesis is challenging because of its heterogeneous structure, i.e., broad molecule weight (MW) distribution and diverse hydroxyl (OH) functionality. This complexity influences the crosslinking reaction between lignin and isocyanate and affects the quality of PU products. Here, we propose a two-step strategy for lignin structure homogenization by lowering its MW and uniforming OH functionality (step 2). Step 1 involves a bioethanol fractionation process, yielding fractionated lignin with one order lower MW than the raw lignin while exhibiting better processability for the subsequent process. Step 2 is performed by an oxyalkylation process using fractionated lignin that converts phenolic and carboxylic OHs to aliphatic OHs. As a result, we obtained structure-homogenized lignin with good compatibility and crosslinking with hexamethylene diisocyanate for PU coating synthesis. Moreover, PU coatings prepared from structure-homogenized lignin display a defect-free microscopic structure and show better corrosion resistance than coatings fabricated from its raw lignin alternative. Overall, the structure homogenization process is a beneficial way of using lignin as biopolyol in PU synthesis toward the application-oriented design of corrosion-resistant lignin-based PU coatings.",

keywords = "Anticorrosive coating, Biorefinery lignin, Polyurethane, Structure homogenization",

author = "Xiang Wang and Nayanathara, {R. M.Oshani} and Weiqi Leng and Caldona, {Eugene B.} and Liyang Liu and Advincula, {Rigoberto C.} and Zhao Zhang and Xuefeng Zhang",

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year = "2022",

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doi = "10.1016/j.jafr.2022.100452",

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T1 - Corrosion-resistant polyurethane coatings from structure-homogenized biorefinery lignin through fractionation and oxypropylation

AU - Wang, Xiang

AU - Nayanathara, R. M.Oshani

AU - Leng, Weiqi

AU - Caldona, Eugene B.

AU - Liu, Liyang

AU - Advincula, Rigoberto C.

AU - Zhang, Zhao

AU - Zhang, Xuefeng

PY - 2022/12

Y1 - 2022/12

N2 - Using lignin for polyurethane (PU) synthesis is challenging because of its heterogeneous structure, i.e., broad molecule weight (MW) distribution and diverse hydroxyl (OH) functionality. This complexity influences the crosslinking reaction between lignin and isocyanate and affects the quality of PU products. Here, we propose a two-step strategy for lignin structure homogenization by lowering its MW and uniforming OH functionality (step 2). Step 1 involves a bioethanol fractionation process, yielding fractionated lignin with one order lower MW than the raw lignin while exhibiting better processability for the subsequent process. Step 2 is performed by an oxyalkylation process using fractionated lignin that converts phenolic and carboxylic OHs to aliphatic OHs. As a result, we obtained structure-homogenized lignin with good compatibility and crosslinking with hexamethylene diisocyanate for PU coating synthesis. Moreover, PU coatings prepared from structure-homogenized lignin display a defect-free microscopic structure and show better corrosion resistance than coatings fabricated from its raw lignin alternative. Overall, the structure homogenization process is a beneficial way of using lignin as biopolyol in PU synthesis toward the application-oriented design of corrosion-resistant lignin-based PU coatings.

AB - Using lignin for polyurethane (PU) synthesis is challenging because of its heterogeneous structure, i.e., broad molecule weight (MW) distribution and diverse hydroxyl (OH) functionality. This complexity influences the crosslinking reaction between lignin and isocyanate and affects the quality of PU products. Here, we propose a two-step strategy for lignin structure homogenization by lowering its MW and uniforming OH functionality (step 2). Step 1 involves a bioethanol fractionation process, yielding fractionated lignin with one order lower MW than the raw lignin while exhibiting better processability for the subsequent process. Step 2 is performed by an oxyalkylation process using fractionated lignin that converts phenolic and carboxylic OHs to aliphatic OHs. As a result, we obtained structure-homogenized lignin with good compatibility and crosslinking with hexamethylene diisocyanate for PU coating synthesis. Moreover, PU coatings prepared from structure-homogenized lignin display a defect-free microscopic structure and show better corrosion resistance than coatings fabricated from its raw lignin alternative. Overall, the structure homogenization process is a beneficial way of using lignin as biopolyol in PU synthesis toward the application-oriented design of corrosion-resistant lignin-based PU coatings.

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KW - Biorefinery lignin

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Corrosion-resistant polyurethane coatings from structure-homogenized biorefinery lignin through fractionation and oxypropylation

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