Robust, malleable, degradable, self-healable, weldable and recyclable polyimine thermosets from natural peach gum and chitosan

The increase in nondegradable polymer waste and the depletion of nonrenewable fossil resources result in environmental concerns and unsustainable industrial development. It is significant to fabricate polymer thermosets with degradable, self-healable, weldable and recyclable performances from biomas...

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Bibliographic Details
Published in:Polymer chemistry 2024-08, Vol.15 (32), p.3287-3299
Main Authors: Zhang, Ningning, Pan, Xianjie, Xi, Aoqian, Chen, Wenpei, Huang, Ting, Zeng, Yanning
Format: Article
Language:English
Subjects:
Adhesive strength
Biomass
Bonding strength
Chemical synthesis
Chitosan
Decomposition reactions
Imines
Industrial development
Mechanical properties
Modulus of elasticity
Networks
Polyazomethines
Polyimide resins
Polymers
Polysaccharides
Recycling
Reprocessing
Shape memory
Tensile strength
Thermal stability
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Summary:The increase in nondegradable polymer waste and the depletion of nonrenewable fossil resources result in environmental concerns and unsustainable industrial development. It is significant to fabricate polymer thermosets with degradable, self-healable, weldable and recyclable performances from biomass. Herein, for the first time, natural peach gum (PG) as an attractive feedstock was employed to prepare degraded and recycled polyimine (PI) networks, due to the hydrolysable and renewable nature of PG. Firstly a peach gum polysaccharide with pendent -CHO groups (PGP-CHO) was synthesized through a graft reaction between 4-formylbenzoic acid and PGP; then it was cured with chitosan (CS) via a moderate and catalyst-free Schiff base reaction resulting in fully biobased PI networks (PGCS). The resultant PGCS-100 networks display good mechanical properties (tensile strength of ∼56.5 MPa and Young's modulus of ∼439 MPa) and high thermal stability (initial decomposition temperature around 227.1 °C). Meanwhile, the PGCS-100 network containing the most dynamic imine bonds exhibits superior self-healing, welding, shape memory and reprocessing performances. Moreover, PGCS-100 can be degraded completely under acidic conditions, allowing sustainable recycling. Furthermore, PGCS-100 can be applied in recycled adhesion, exhibiting excellent adhesion strength (10.5 MPa). Briefly, a new strategy to develop green environmentally friendly PI networks with high performance from biomass is provided, contributing to the reduction of polymer waste and sustainable industrial development. Bio-based PI networks (PGCS) exhibit good mechanical properties, high thermal stability, degradability, recyclability and healing ability.
ISSN:1759-9954
1759-9962
DOI:10.1039/d4py00473f