Synthesis of hydrophobic biopolyesters from depolymerized Pinus radiata bark suberin
Author:
Quilter Helena C.1, Risani Regis2, Gallagher Suzanne1, Robertson Michael1, Thumm Armin1, Thomas Hayden P.1, Abbel Robert1ORCID
Affiliation:
1. Chemistry and Physics Research Group , 6982 Scion , Tītokorangi Drive , Rotorua 3010 , New Zealand 2. Materials, Engineering and Manufacturing Research Group , 6982 Scion , Tītokorangi Drive , Rotorua 3010 , New Zealand
Abstract
Abstract
The bark of Pinus radiata offers an underutilized source of high-value renewable chemicals such as extractable polyphenols and lipophilic compounds (waxes and suberin). Here, the depolymerization and extraction of suberin from P. radiata bark and its repolymerization to form novel polyesters are reported. Three different strategies were evaluated for repolymerization of the suberin monomers, with starting materials and products characterized using chemical and thermal analysis techniques. The inclusion of comonomer (1,12-dodecanediol) to provide stoichiometric balance improved the conversion, product yield, solubility and increased molecular weight. Enzymatic polymerization conditions gave the highest yield, while the highest molecular weight was achieved using titanium butoxide, demonstrating that polymerization conditions could be varied to target desired product properties. Products were hydrophobic, as shown by contact angles, ϴ ≥ 90° after 30 s. This work highlights opportunities for utilizing suberin to add value to a P. radiata bark biorefinery concept. Potential future applications include its use as a starting material for novel bio-based polymers that can serve as water-repellent surfaces and coatings, replacing established products derived from fossil resources.
Funder
Ministry of Business, Innovation and Employment
Publisher
Walter de Gruyter GmbH
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