On the improvement of properties of bioplastic composites derived from wasted cottonseed protein by rational cross-linking and natural fiber reinforcement

An approach of largely improving the properties of protein-based biopolymers is reported. Cottonseed protein concentrate (CPC) purified from cottonseed protein powder waste, with a protein content of >70% and a plasticizing efficiency of 4.2, was used to produce bioplastic polymer. A prepreg cons...

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Bibliographic Details
Published in:Green chemistry : an international journal and green chemistry resource : GC 2020-12, Vol.22 (24), p.8642-8655
Main Authors: Yue, Hangbo, Zheng, Yuru, Zheng, Pingxuan, Guo, Jianwei, Fernández-Blázquez, Juan P, Clark, James H, Cui, Yingde
Format: Article
Language:English
Subjects:
Adhesive strength
Biopolymers
Bonding strength
Chemical bonds
Composite materials
Contact angle
Crosslinking
Fiber reinforcement
Glass transition temperature
Green chemistry
Hydrophobicity
Interfaces
Interfacial bonding
Mechanical properties
Natural resources
NMR
Nuclear magnetic resonance
Polymer matrix composites
Polymers
Proteins
Raw materials
Sisal
Starch
Tensile strength
Thermal stability
Transition temperatures
Water resistance
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Summary:An approach of largely improving the properties of protein-based biopolymers is reported. Cottonseed protein concentrate (CPC) purified from cottonseed protein powder waste, with a protein content of >70% and a plasticizing efficiency of 4.2, was used to produce bioplastic polymer. A prepreg consisting of relatively oriented sisal fiber (SF) was transferred into CPC matrix as reinforcement, giving rise to improved mechanical properties of CPC/SF composites. To enhance interfacial bonding forces between the fiber and polymer, dialdehyde starch, DAS, with varied content (5-30 wt%) was introduced, and the FTIR and NMR results showed that DAS can effectively bridge biomacromolecular chains and form strong chemical bonds within the crosslinked structure. This cross-linking treatment leads to the formation of tight CPC/SF interfaces with strong adhesion, as shown by microscopic images, translating into excellent mechanical performance ( e.g. tensile strength 21 MPa), water resistance ( e.g. water contact angle 80°) and thermal stability ( e.g. glass transition temperature 104 °C) of the composites. The all green composites derived from natural resources with comparable or even superior properties to state-of-the-art biomass-based composites hold great potential for being utilized in larger industries. Biocomposites made entirely by renewable biomass demonstrate excellent mechanical, hydrophobic and thermal properties thanks to rational cross-linking and fiber reinforcement.
ISSN:1463-9262
1463-9270
DOI:10.1039/d0gc03245j