Highly Enhanced Mechanical Strength and Toughness of Biodegradable PBAT Plastics through a Biobased Multiple Hydrogen Bonding Strategy

Fei, Zhi-Xiong; Sun, Jingrui; Cui, Chang; Yin, Chenxiao; Zhan, Rui; Shi, Ling-Ying; Yang, Ke-Ke; Wang, Yu-Zhong

doi:10.1021/acs.macromol.4c01153

Macromolecules

2024

DOI: 10.1021/acs.macromol.4c01153

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Highly Enhanced Mechanical Strength and Toughness of Biodegradable PBAT Plastics through a Biobased Multiple Hydrogen Bonding Strategy

Zhi-Xiong Fei,

Jingrui Sun,

Chang Cui

et al.

Abstract: Poly(butyleneadipate-co-terephthalate) (PBAT), a favorable biodegradable polyester, exhibits striking application potential as a sustainable alternative of conventional petrochemical plastics to relieve the problems on environmental pollution. However, the utilization of PBAT materials is still limited due to their suboptimal strength and toughness. Here, we utilized melting chain extension reaction to incorporate multiple hydrogen bonding units into the main chain of PBAT, achieving the great enhancement in m… Show more

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Cited by 2 publications

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Enhanced poly(butylene adipate‐co‐terephthalate) composite films reinforced with nano‐calcium carbonate modified by a comb‐like polyacrylic superdispersant

Li,

Sun,

Liang

et al. 2024

Polymer Composites

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A comb‐like polyacrylic superdispersant (CPS) consisting of polyacrylic acid‐co‐poly(isobutyl alcohol polyoxyethylene ether) (PBAT) was synthesized as a dispersant for preparing nano‐calcium carbonate/PBAT (nano‐CaCO3/PBAT) composite through internal mixing. Chemical structure analysis revealed that CPS adsorbed onto the surface of nano‐CaCO3 via coordination between carboxyl groups and calcium ions, effectively dispersing particles using a comb‐shaped side chain and electrostatic repulsion. This improved compatibility between nano‐CaCO3 and PBAT resulted in enhanced crystallinity, tensile stress, and elongation at break. By incorporating only 0.4 wt% CPS into 10 wt% nano‐CaCO3 (based on PBAT weight), the dispersion of nano‐CaCO3 was significantly improved, leading to a superior two‐phase interface in the composite material. Consequently (in the film's machine direction), elongation at break increased from 882 ± 49% to 1047 ± 31%, while tensile strength increased from 22.10 ± 2.06 MPa to 26.70 ± 1.14 MPa. These findings facilitate the production of high‐performance PBAT composites suitable for blow molding into biodegradable films.Highlights Comb‐like polyacrylic superdispersant synthesized by aqueous polymerization. Nano‐CaCO3 modified via the adsorption and dispersion of CPS. Stress and elongation of PBAT composite reinforced by CPS‐modified nano‐CaCO3. CPS‐modified nano‐CaCO3/PBAT composite films processed through blow molding. Enhancement by coordination, hydrogen‐bond action, and microphase separation.

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Enhanced poly(butylene adipate‐co‐terephthalate) composite films reinforced with nano‐calcium carbonate modified by a comb‐like polyacrylic superdispersant

Li,

Sun,

Liang

et al. 2024

Polymer Composites

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show abstract

Simultaneous Enhanced Mechanical Properties and Foamability of Biodegradable PBAT via Physical Cross-Linking through Reactive Blending

Yang,

Ling,

et al. 2024

ACS Appl. Polym. Mater.

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While fully biodegradable poly(butylene adipate-coterephthalate) (PBAT) is considered to be one of the most promising materials, the application of PBAT materials is still hindered due to its intrinsic low mechanical strength and poor foamability. Herein, a strategy is addressed to construct PBATbased supramolecular bionanocomposites of high strength and excellent foamability with homogeneous dispersion of UPy aggregates via quadruple hydrogen bonding. The biocomposite was prepared by direct melt-blending of isocyanate-terminal ureidopyrimidinone (UPy-NCO) and PBAT. It was found that the terminal hydroxyl group of PBAT quickly reacted with the isocyanate group of UPy-NCO during the mixing and in-situ formed a dimerized supramolecular polymer (PBAT-UPy-UPy-PBAT) owing to quadruple hydrogen bonding. The PBAT-UPy-UPy-PBAT could be further folded via longitudinal hydrogenbonding interactions between the ureido groups of UPy units, forming ordered needle-like UPy nanoassemblies in the PBAT matrix. Such particular nanoassemblies could function as physical cross-linking points for PBAT-based composites, resulting in simultaneous improved mechanical strength and foamability of PBAT. This work paves a feasible avenue for manufacturing high-performance PBAT biocomposites and corresponding foams, which is challenging in existing industrial technologies.

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Highly Enhanced Mechanical Strength and Toughness of Biodegradable PBAT Plastics through a Biobased Multiple Hydrogen Bonding Strategy

Cited by 2 publications

References 45 publications

Enhanced poly(butylene adipate‐co‐terephthalate) composite films reinforced with nano‐calcium carbonate modified by a comb‐like polyacrylic superdispersant

Enhanced poly(butylene adipate‐co‐terephthalate) composite films reinforced with nano‐calcium carbonate modified by a comb‐like polyacrylic superdispersant

Simultaneous Enhanced Mechanical Properties and Foamability of Biodegradable PBAT via Physical Cross-Linking through Reactive Blending

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